http://forwhattheywereweare.wordpress.com/2012/04/27/ancient-mitochondrial-dna-from-the-basque-country-and-cantabria-unmistakable-mtdna-h-in-magdalenian-cantabria/

Anyway this post talks about it...and apparently it finds some ancient H in paleolithic which effectively means game over on this nonsense anyway - but no, the internet keeps this bullshit alive until it's 100% absolutely proven otherwise. But if you have H that far back before neolithic it's really hard to argue H and r1b spread from east.

http://forwhattheywereweare.wordpress.com/2012/04/27/ancient-mitochondrial-dna-from-the-basque-country-and-cantabria-unmistakable-mtdna-h-in-magdalenian-cantabria/

Anyway this post talks about it...and apparently it finds some ancient H in paleolithic which effectively means game over on this nonsense anyway - but no, the internet keeps this bullshit alive until it's 100% absolutely proven otherwise. But if you have H that far back before neolithic it's really hard to argue H and r1b spread from east.

I don't know how for sure those H's are and H6 in Upper Paleolithic Europeans makes no sense, i would expect H3. There isn't much maternal continuum in Europe since the Mesolithic and that's just fact ancient mtDNA has proven it, so really there is no chance that somehow all the H lineages in Europe today where there before the Neolithic. At some point all European's ancestors came from the east and why would mtDNA H in Upper Paleolithic Europe be evidence R1b(which has only one clade in Europe that's 5,000 years old) originated in Europe? The genetic origin of all the differnt people in Europe is complicated and European aka Mesolithic European aka WHG are just one major ancestral group to modern Europeans there is also WHG's brother ANE and middle eastern ancestry(mainly from Stuttgart like farmers). No one is arguing for complete or vast majority genetic continuum in Europe since the Mesolithic anymore.

http://dienekes.blogspot.com/2014/02/human-admixture-common-in-human-history.html

No significant race mixing detected in UK for many thousands of years. So if they came to europe, they did so on magic carpets and didn't find anyone here when they came.
No significant mixing for many thousands of years in the UK? :icon_rolleyes: Have you seen such word as "uncertain" after the comma?. There was an obvious mixing giving the history and genetic data.

And the Dienekes himself states:


The case of Northwestern Europe appears especially striking as none of the populations from the region show evidence of admixture. This may be because the mixtures taking place there (e.g., between "Celts" and "Anglo-Saxons" in Great Britain) involved populations that were not strongly differentiated. Alternatively, population admixture history may have preceded the last few thousand years and is thus beyond the temporal scope of this method.

Anglo Saxons and Britons mixed, that was less than 2,000 years ago.

I guess a good question to pose is what happened to all the mesolithic/paleolithic mtdna lineages? If we don't include H in that equation, then you'd be hard pressed to find a spot in the entirety of Europe to surpass 25%. Yet aren't a lot of places in Europe supposed to be 50% or more mesolithic/paleolithic, and most of the migrations that diluted that supposed to have been male dominated?

I guess a good question to pose is what happened to all the mesolithic/paleolithic mtdna lineages? If we don't include H in that equation, then you'd be hard pressed to find a spot in the entirety of Europe to surpass 25%. Yet aren't a lot of places in Europe supposed to be 50% or more mesolithic/paleolithic, and most of the migrations that diluted that supposed to have been male dominated?

I know its confusing but so far seems to be true. The vast majority of European maternal lineages are most likely descended from near eastern farmers(or modern-like near easterns) even ones who have majority Mesolithic ancestry. Mesolithic/Upper Paleolithic European mtDNA is probably more complex so maybe the percentage is higher than around 12-15% on average.

I know its confusing but so far seems to be true. The vast majority of European maternal lineages are most likely descended from near eastern farmers(or modern-like near easterns) even ones who have majority Mesolithic ancestry. Mesolithic/Upper Paleolithic European mtDNA is probably more complex so maybe the percentage is higher than around 12-15% on average.

God damn this site is dragging ass right now...Anyways.
I ask: Where/how did all the paleo/meso mtdna lineages go?
You say: Yes they did.
O_o

No significant mixing for many thousands of years in the UK? :icon_rolleyes: Have you seen such word as "uncertain" after the comma?. There was an obvious mixing giving the history and genetic data.

And the Dienekes himself states:

Mixing of populations that are already close together won't cause linkage disequillibrium, because no truly novel genes are being introduced.

Dienekes is smart in some ways but very biased towards swarthcentricity. He is also kind of dumb/ridiculous in other ways...some of his posts are just a joke.

Neolithic people came and multiplied, then got beaten back.

http://dienekes.blogspot.com/2013/09/neolithic-boom-and-bust-in-ireland.html

Ireland isn't the only place that U is more common anciently, becomes totally rare, then becomes more common again. Basically neolithic sites were invaders, and invaders eventually mixed with or got dominated by the natives. Apparently climate change was part of it.

http://dienekes.blogspot.com/2013/04/mtdna-haplogroup-h-and-origin-of.html

This study shows that H spread from west to east, using molecular clock style paternity checks and looking at the samples of H throughout time.

Archaeologically we know that LBK got wiped out catastrophically, so the idea that it spread by land through neolithic farmers is not really an option.

I don't know how for sure those H's are and H6 in Upper Paleolithic Europeans makes no sense, i would expect H3. There isn't much maternal continuum in Europe since the Mesolithic and that's just fact ancient mtDNA has proven it, so really there is no chance that somehow all the H lineages in Europe today where there before the Neolithic. At some point all European's ancestors came from the east and why would mtDNA H in Upper Paleolithic Europe be evidence R1b(which has only one clade in Europe that's 5,000 years old) originated in Europe? The genetic origin of all the differnt people in Europe is complicated and European aka Mesolithic European aka WHG are just one major ancestral group to modern Europeans there is also WHG's brother ANE and middle eastern ancestry(mainly from Stuttgart like farmers). No one is arguing for complete or vast majority genetic continuum in Europe since the Mesolithic anymore.

We just guess there's none because we have not run the proper tests to tell for sure. They assumed there was none, because they did not want to find continuity because the spanish are more related to neolithic than the basques are. They are incredibly biased.

We just guess there's none because we have not run the proper tests to tell for sure. They assumed there was none, because they did not want to find continuity because the spanish are more related to neolithic than the basques are. They are incredibly biased.

You assume everyone is biased, when most of the time they are not. I agree it is totally possible there are Mesolithic/Upper Palaeolithic European H lineages. The latest mtDNA tests of Mesolithic Europeans have turned up all U5, U4, and U2e though.

God damn this site is dragging ass right now...Anyways.
I ask: Where/how did all the paleo/meso mtdna lineages go?
You say: Yes they did.
O_o

I don't know how it happened all i know is it did.

Mixing of populations that are already close together won't cause linkage disequillibrium, because no truly novel genes are being introduced.
Indeed. But it also should indicate relatively young age of those populations(in terms of common ancestry), because I don't expect a scenario when two old populations are being still close to each other due to the isolation of both.. Pretty much everything was formed abt.3000-2500 BC and onwards, giving the y-chromosomal estimations and autosomal data.


We just guess there's none because we have not run the proper tests to tell for sure. They assumed there was none, because they did not want to find continuity because the spanish are more related to neolithic than the basques are. They are incredibly biased.
It clearly depends on a region. Basques aren't that less neolithic than Spaniards are. French_Basque from this PCA is basically a very-slightly northern-shifted Basque
http://s30.postimg.org/e0n3efetc/1pca12.jpg
Then look at the big red dot meaning a position of La-Brana. Huge genetical gap, isn't it? Even if some paleolithic or mesolithic lines exist among Basques ,population was hugely replaced.

Northern Greeks mtDNA=318

1.H(H)=133 41.8%* of total, sub=46, H*(H)=87

2.H5(H)=14, 30.4% of H, 12.73% of total, sub=0

2.H8'31'11'12'91(H)=10, 21.74% of H(H), 9.1% of total, sub=10

3.H8(H)=5 50%* of H8'31'11'12'91(H), 10.87% of H(H), 4.5% of total, sub=0

3.H12(H)=4 40%* of H8'31'11'12'91(H), 8.7% of H(H), 3.6% of total, sub=0

3.H11a(H)=1 10%* of H8'31'11'12'91(H), 2.17% of H(H), 0.9% of total, sub=0

2.H1(H)=9 19.5% of H(H), 8.18% of total, sub=9

3.H1b(H)=4 44.4%* of H1(H), 8.7% of H(H), 3.6% of total, sub=0

3.H1c(H)=3 33.3%* of H1(H), 6.5% of H(H), 2.72% of total, sub=0

3.H1a(H)=2 22.2%* of H1(H), 4.3% of H(H), 1.8% of total, sub=1

4.H1a1=1 100% of H1a, 22.2% of H1, 4.3% of H(H), 1.8% of total, sub=0

2.H20(H)=4 8.7% of H(H), 3.6% of total, sub=0

2.H14a(H)=3 6.5% of H(H), 2.7% of total, sub=0

2.H2a1(H)=2 4.3% of H(H), 1.8% of total, sub=0

2.H9(H)=2 4.3% of H(H), 1.8% of total, sub=0

2.H6(H)=2 4.3% of H(H), 1.8% of total, sub=0

1.U(U)=52 16.35%* of total, sub=52

2.U5(U)=15 28.8%* of U(U), 4.7%* of total, sub=15

3.U5a(U)=12 80%* of U5(U), 23%* of U(U), 3.77%* of total, sub=10

4.U5a1(U)=10 100% of U5a(U), 80% of U5(U), 23% of U(U), 3.77% of total, sub=0

3.U5b(U)=3 20%* of U5(U), 5.77%* of U(U), 0.9%* of total, sub=2

4.U5b1b(U)=2 100% of U5b(U), 20% of U5(U), 5.77% of U(U), 0.9% of total, sub=0

2.U4(U)=14 27%* of U(U), 4.4%* of total, sub=0

2.U3(U)=12 23%* of U(U), 3.77%* of total, sub=5

3.U3a(U)=5 100% of U3(U), 23% of U(U), 3.77% of total, sub=0

2.U1(U)=6 11.5%* of U(U), 1.88%* of total, sub=4

3.U1a(U)=4 100% of U1(U), 11.5% of U(U), 1.88% of total, sub=0

2.U6?(U)=2 3.8%* of U(U), 0.6%* of total, sub=0

2.U7(U)=2 3.8%* of U(U), 0.6%* of total, sub=0

2.U2e(U)=1 1.9%* of U(U), 0.3%* of total, sub=0

1.J(J)=33 10.377%* of total, sub=33

2.J1(J)=29 87.8%* of J(J), 9.12%* of total, sub=18

3.J1c(J)=14 77.7%* of J1(J), 68% of J(J), 7.1% of total, sub=0

3.J1b(J)=4 22.2% of J1(J), 19.5% of J(J), 2% of total, sub=3

4.J1b1(J)=3 100% of J1b(J), 22.2% of J1(J), 19.5% of J(J), 2% of total, sub=0

2.J2(J)=4 12.12%* of J(J), 1.25%* of total, sub=1

3.J2b(J)=1 100% of J2(J), 12.12% of J(J), 1.25% of total, sub=0

1.T(T)=27 8.5%* of total, sub=22

2.T1(T)=13 59% of T(T), 5% of total, sub=9

3.T1a(T)=5 55.5% of T1(T), 32.8% of T(T), 2.78% of total, sub=0

3.T1b(T)=4 44.45 of T1(T), 26.5% of T(T), 2.23% of total, sub=0

2.T2(T)=9 41% of T(T), 3.47% of total, sub=1

3.T2b(T)=1 100% of T2(T), 41% of T(T), 3.47% of total, sub=0

1.K(K)=16 5% of total, sub=16

2.K1(K)=15 93.75%* of K(K), 4.75* of total, sub=14

3.K1a(K)=10 71.4% of K1(K), 67% if K(K), 3.37% of total, sub=0

3.K1c=4 28.57% of K1(K), 26.78% of K(K), 1.3% of total, sub=0

2.K2b(K)=1 6.25%* of K(K), 0.31%* of total, sub=0

1.X2(X)=12 3.77%* of total, sub=2

2.X2b(X)=1 50% of X2(X), 1.886% of total, sub=0

2.X2g(X)=1 50% of X2(X), 1.886% of total, sub=0

1.HV0(HV0)=9 2.42%* of total, sub=0

1.I(I)=9 2.45* of total, sub=2

2.I1a(I)=2 100% of I(I), 2.45% of total, sub=0

1.W(W)=8 2.5%* of total, sub=0

1.R0a(R0a)=7 2.2%* of total, sub=0

1.N1(N)=3 0.945* of total, sub=2

2.N1a(N)=1 50% of N1(N), 0.47% of total, sub=0

2.N1b1(N)=1 50% of N1(N), 0.47% of total, sub=0

1.M5a(M)=3 0.945%* of total, sub=0

1.R*(R)=2 0.635* of total, sub=0

1.HV*(HV)=2 0.635* of total, sub=0

1.C*(C)=1 0.3%* of total, sub=0

Epirus (https://www.google.com/maps/place/Technological+Educational+Institute+of+Epirus/@38.4948279,22.0814835,6z/data=!4m2!3m1!1s0x135c1b5e278e3d7f:0x856ad7a62eadd 523)

mtDNA=17

1.H(H)=8 47%* of total, sub=0

1.U(U)=3 17.6%* of total, sub=0

1.HV(HV)=2 11.7%* of total, sub=0

1.I(I)=1 5.9%* of total, sub=0

1.J(J)=1 5.9%* of total, sub=0

1.K(K)=1 5.9%* of total, sub=0

1.T(T)=1 5.9%* of total, sub=0

Thessaly mtDNA=10

1.HV(HV)=4 40%* of total, sub=0

1.H(H)=3 30%* of total, sub=0

1.K(K)=1 10%* of total, sub=0

1.T(T)=1 10%* of total, sub=0

1.W(W)=1 10%* of total, sub=0

Peloponnese mtDNA=9

1.H(H)=3 33.3%* of total, sub=0

1.HV(HV)=2 22.2%* of total, sub=0

1.J(J)=1 11.1%* of total, sub=0

1.K(k)=1 11.1%* of total, sub=0

1.T(T)=1 11.1%* of total, sub=0

1.X(X)=1 11.1%* of total, sub=0

Central Macedonia mtDNA=9

1.H(H)=8 88.8%* of total, sub=0

1.K(K)=1 11.1%* of total, sub=0

Central Greece mtDNA=4


1.J(J)=3 75%* of total, sub=0

1.H(H)=1 25%* of total, sub=0



Island of Chios mtDNA=5



1.T(T)=2 40%* of total, sub=0

1.K(K)=1 20%* of total, sub=0

1.HV(HV)=1 20%* of total, sub=0

1.H(H)=1 20%* of total, sub=0


South eastern Europe total, mtDNA=372

1.H(H)=157 42.2%* of total, sub=46(H*(H)=87)

2.H5(H)=14, 30.4% of H, 12.8% of total, sub=0

2.H8'31'11'12'91(H)=10, 21.74% of H(H), 9.17% of total, sub=10

3.H8(H)=5 50%* of H8'31'11'12'91(H), 10.87% of H(H), 4.6% of total, sub=0

3.H12(H)=4 40%* of H8'31'11'12'91(H), 8.7% of H(H), 3.7% of total, sub=0

3.H11a(H)=1 10%* of H8'31'11'12'91(H), 2.17% of H(H), 0.917% of total, sub=0

2.H1(H)=9 19.5% of H(H), 8.25% of total, sub=9

3.H1b(H)=4 44.4%* of H1(H), 8.7% of H(H), 3.7% of total, sub=0

3.H1c(H)=3 33.3%* of H1(H), 6.5% of H(H), 2.75% of total, sub=0

3.H1a(H)=2 22.2%* of H1(H), 4.3% of H(H), 1.8% of total, sub=1

4.H1a1=1 100% of H1a, 22.2% of H1, 4.3% of H(H), 1.8% of total, sub=0

2.H20(H)=4 8.7% of H(H), 3.7% of total, sub=0

2.H14a(H)=3 6.5% of H(H), 2.75% of total, sub=0

2.H2a1(H)=2 4.3% of H(H), 1.8% of total, sub=0

2.H9(H)=2 4.3% of H(H), 1.8% of total, sub=0

2.H6(H)=2 4.3% of H(H), 1.8% of total, sub=0

1.U(U)=55 14.78%* of total, sub=52

2.U5(U)=15 28.8%* of U(U), 4.26% of total, sub=15

3.U5a(U)=12 80%* of U5(U), 23% of U(U), 3.4% of total, sub=10

4.U5a1(U)=10 100% of U5a(U), 80% of U5(U), 23% of U(U), 3.4% of total, sub=0

3.U5b(U)=3 20%* of U5(U), 5.77% of U(U), 0.85% of total, sub=2

4.U5b1b(U)=2 100% of U5b(U), 20% of U5(U), 5.77% of U(U), 0.85% of total, sub=0

2.U4(U)=14 27% of U(U), 4%* of total, sub=0

2.U3(U)=12 23% of U(U), 3.4% of total, sub=5

3.U3a(U)=5 100% of U3(U), 23% of U(U), 3.4% of total, sub=0

2.U1(U)=6 11.5% of U(U), 1.7% of total, sub=4

3.U1a(U)=4 100% of U1(U), 11.5% of U(U), 1.7% of total, sub=0

2.U6?(U)=2 3.8% of U(U), 0.568% of total, sub=0

2.U7(U)=2 3.8% of U(U), 0.568% of total, sub=0

2.U2e(U)=1 1.9% of U(U), 0.28% of total, sub=0

1.J(J)=38 10.2%* of total, sub=33

2.J1(J)=29 87.8% of J(J), 9.% of total, sub=18

3.J1c(J)=14 77.7%* of J1(J), 68% of J(J), 7% of total, sub=0

3.J1b(J)=4 22.2% of J1(J), 19.5% of J(J), 2% of total, sub=3

4.J1b1(J)=3 100% of J1b(J), 22.2% of J1(J), 19.5% of J(J), 2% of total, sub=0

2.J2(J)=4 12.12% of J(J), 1.2% of total, sub=1

3.J2b(J)=1 100% of J2(J), 12.12% of J(J), 1.2% of total, sub=0

1.T(T)=32 8.6%* of total, sub=22

2.T1(T)=13 59% of T(T), 5% of total, sub=9

3.T1a(T)=5 55.5% of T1(T), 32.8% of T(T), 2.8% of total, sub=0

3.T1b(T)=4 44.45 of T1(T), 26.5% of T(T), 2.26% of total, sub=0

2.T2(T)=9 41% of T(T), 3.5% of total, sub=1

3.T2b(T)=1 100% of T2(T), 41% of T(T), 3.5% of total, sub=0

1.K(K)=21 5.6%* of total, sub=16

2.K1(K)=15 93.75% of K(K), 5.3 of total, sub=14

3.K1a(K)=10 71.4% of K1(K), 67% if K(K), 3.78% of total, sub=0

3.K1c=4 28.57% of K1(K), 26.78% of K(K), 1.5% of total, sub=0

2.K2b(K)=1 6.25%* of K(K), 0.35% of total, sub=0

1.X(X)=13 3.5%* of total, sub=12

2.X2(X)=12 100% of X, 3.5% of total, sub=2

2.X2b(X)=1 50% of X2(X), 50% of X(X) 1.74% of total, sub=0

2.X2g(X)=1 50% of X2(X), 50% of X(X), 1.74% of total, sub=0

1.HV0(HV0)=9 2.8%* of total, sub=0

1.I(I)=8 2.5%* of total, sub=2

2.I1a(I)=2 100% of I(I), 2.5% of total, sub=0

1.W(W)=9 2.8%* of total, sub=0

1.R0a(R0a)=7 1.88%* of total, sub=0

1.N1(N)=3 0.8* of total, sub=2

2.N1a(N)=1 50% of N1(N), 0.4% of total, sub=0

2.N1b1(N)=1 50% of N1(N), 0.4% of total, sub=0

1.M5a(M)=3 0.8%* of total, sub=0

1.R*(R)=2 0.5* of total, sub=0

1.HV*(HV)=2 0.5* of total, sub=0

1.C*(C)=1 0.2688%* of total, sub=0

Indeed. But it also should indicate relatively young age of those populations(in terms of common ancestry), because I don't expect a scenario when two old populations are being still close to each other due to the isolation of both.. Pretty much everything was formed abt.3000-2500 BC and onwards, giving the y-chromosomal estimations and autosomal data.

Even if that's true it won't have any effect on these results. Breeding in homogenous won't cause linkage disequillibrium. However, there had to be someone there beforehand if there was some giant migration and this is where it has always fallen apart. Basically they would have had to have killed and eaten them all for this result to be possible. I expect that to show up on news any day. It's possible, but I don't think so.



It clearly depends on a region. Basques aren't that less neolithic than Spaniards are. French_Basque from this PCA is basically a very-slightly northern-shifted Basque
http://s30.postimg.org/e0n3efetc/1pca12.jpg
Then look at the big red dot meaning a position of La-Brana. Huge genetical gap, isn't it? Even if some paleolithic or mesolithic lines exist among Basques ,population was hugely replaced.

Basques claim to be original occupants of iberia going back many thousands of years. They are, at the least, clearly the oldest occupants and have continuous roots going back at least 3-4k years. However the country of spain oppresses them quite a bit and does all it can to cast doubts on such basque claims.

Also I forgot to point out before I got a good laugh about fire hair pointing out about aquitani coming from france. Aquitani, original turdetani, basques all of these are related and borders not only don't stay the same, but there were no such thing as nations like today until relatively recently.

Basques aren't north euros, but current data (from Lazaridis et al paper and genome bloggers working on La Braña) indicates that they form a peak in mesolithic hunter-gatherer ancestry among their own southwest European reference group.

Basques aren't north euros, but current data (from Lazaridis et al paper and genome bloggers working on La Braña) indicates that they form a peak in mesolithic hunter-gatherer ancestry among their own southwest European reference group.
Yeah, they are not supposed to be north euros obviously. They are irish are more related in their neanderthal characteristics - and the very fact these survive at all tells me they are at least partially ancient to the area.

Iraq mtDNA=51

1.J(J)=11 21.56%* of total, sub=11

2.J1(J)=10 90.09%* of J(J), 19.6%* of total, sub=0

2.J2(J)=1 9.09%* of J(J), 2%* of total, sub=0

1.U(U)=11 21.56%* of total, sub=11

2.U3(U)=3 27.27%* of U(U), 5.88%* of total, sub=0

2.U7(U)=3 27.27%* of U(U), 5.88%* of total, sub=0

2.U2(U)=2 18.18%* of U(U), 4%* of total, sub=0

2.U1(U)=1 9.1%* of U(U), 2%* of total, sub=0

2.U4(U)=1 9.1%* of U(U), 2%* of total, sub=0

2.U6(U)=1 9.1%* of U(U), 2%* of total, sub=0

1.H(H)=8 15.68%* of total, sub=0

1.HV(HV)=6 11.76%* of total, sub=0

1.T(T)=5 9.8%* of total, sub=0

1.K(K)=4 7.8%* of total, sub=0

1.R0(R0)=3 5.9%* of total, sub=0

1.M(M)=1 2%* of total, sub=0

1.R*(R)=1 2%* of total, sub=0

1.R2(R)=1 2%* of total, sub=0

Jordon-total mtDNA=290

1.H(H)=76 26%* of total, sub=0

1.U(U)=56 19.3%* of total, sub=35(U*=1)

2.U3(U)=23 65.7% of U(U), 12.7% of total, sub=0

2.U1(U)=5 14.28% of U(U), 2.76% of total, sub=5

3.U1b(U)=3 60%* of U1(U), 8.57% of U(U), 1.6% of total, sub=0

3.U1a(U)=2 40%* of U1(U), 5.7% of U(U), 1.1% of total, sub=0

2.U5(U)=2 5.7% of U(U), 1.1% of total, sub=1

3.U5a1(U)=1 100% of U(U), 5.7% of U(U), 1.1% of total, sub=0

2.U4(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U2e(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U8b/U2d(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U8b(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U9(U)=1 2.8% of U(U), 0.55% of total, sub=0

1.L(L)=29 10%* of total, sub=27(-(L01)=2)

2.L3(L3)=17 63% of L(L), 6.3% of total, sub=10

3.L3b'f(L3)=7 70% of L3(L3), 44% of L(L), 4.4% of total, sub=7

4.L3b(L3)=5 71.4%* of L3b'f(L3), 50% of L3(L3), 31.4% of L(L), 3.14% of total, sub=1

5.L3b1(L3)=1 100% of L3b(L3), 71.4% of L3b'f(L3), 50% of L3(L3), 31.4% of L(L), 3.14% of total, sub=0

4.L3f1(L3)=2 28.57%* of L3b'f(L3),20% of L3(L3), 12.6% of L(L), 1.26% of total, sub=0

3.L3e'i'k'x(L3)=2 20% of L3(L3), 12.6% of L(L), 1.26% of total, sub=2

4.L3i2(L3), former L3w=1 50%* of L3e'i'k'x(L3), 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

4.L3x2(L3), former L3w=1 50%* of L3e'i'k'x(L3), 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

3.L3d2(L2)=1 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

2.L2(L2)=7 26% of L(L), 2.6% of total, sub=5

Iraq mtDNA=51

1.J(J)=11 21.56%* of total, sub=11

2.J1(J)=10 90.09%* of J(J), 19.6%* of total, sub=0

2.J2(J)=1 9.09%* of J(J), 2%* of total, sub=0

1.U(U)=11 21.56%* of total, sub=11

2.U3(U)=3 27.27%* of U(U), 5.88%* of total, sub=0

2.U7(U)=3 27.27%* of U(U), 5.88%* of total, sub=0

2.U2(U)=2 18.18%* of U(U), 4%* of total, sub=0

2.U1(U)=1 9.1%* of U(U), 2%* of total, sub=0

2.U4(U)=1 9.1%* of U(U), 2%* of total, sub=0

2.U6(U)=1 9.1%* of U(U), 2%* of total, sub=0

1.H(H)=8 15.68%* of total, sub=0



1.HV(HV)=6 11.76%* of total, sub=0

1.T(T)=5 9.8%* of total, sub=0

1.K(K)=4 7.8%* of total, sub=0

1.R0(R0)=3 5.9%* of total, sub=0

1.M(M)=1 2%* of total, sub=0

1.R*(R)=1 2%* of total, sub=0

1.R2(R)=1 2%* of total, sub=0


Amman Jordan mtDNA=101


1.H(H)=31 30.7%* of total, sub=0

1.U(U)=17 16.8%* of total, sub=16

2.U3(U)=6 37.5% of U(U), 6.3% of total, sub=0

2.U1(U)=4 25% of U(U), 4.2% of total, sub=4

3.U1b=3 75%* of U1(U), 18.75% of U(U), 3.15% of total, sub=0

3.U1a(U)=1 25%* of U1(U), 6.25% of U(U), 1% of total, sub=0

2.U9(U)=1 6.25% of U(U), 1% of total, sub=0

2.U8b/U2d(U)=1 6.25% of U(U), 1% of total, sub=0

2.U2e(U)=1 6.25% of U(U), 1% of total, sub=0

2.U4(U)=1 6.25% of U(U), 1% of total, sub=0

2.U5(U)=1 6.25% of U(U), 1% of total, sub=0

2.U8b(U)=1 6.25% of U(U), 1% of total, sub=0

1.L(L)=11 11%* of total, sub=11

2.L3(L3)=5 45.4%* of L(L), 5%* of total, sub=4(L3*=1)

3.L3e'i'k'x(L3)=2 50% of L3(L3), 22.7% of L(L), 2.47% of total, sub=2

4.L3i2 former L3w(L3)=1 50%* of L3e'i'k'x(L3), 25% of L3(L3), 11.36% of L(L), 1.23% of total, sub=0

4.L3x2(L3)=1 50%* of L3e'i'k'x(L3), 25% of L3(L3), 11.36% of L(L), 1.23% of total, sub=0

3.L3b1(L3)=1 25% of L3(L3), 11.36% of L(L), 1.23% of total, sub=0

3.L3d2(L3)=1 25% of L3(L3), 11.36% of L(L), 1.23% of total, sub=0

2.L2(L2)=3 27.27%* of L(L), 3%* of total, sub=3

3.L2a1(L2)=2 66.7%* of L2(L2), 18.18%* of L(L), 2%* of total, sub=0

3.L2c2(L2)=1 33.3%* of L2(L2), 9.09%* of L(L), 1%* of total, sub=0

2.L0a1(L0)=2 18.18%* of L(L), 2%* of total, sub=1

3.L0a1a(L0)=1 100% of L0a1(L0), 18.18% of L(L), 2% of total, sub=0

2.L1b1(L1)=1 9.09%* of L(L), 1%* of total, sub=0

1.T(T)=10 10%* of total, sub=8(T*=2)

2.T2(T)=4 50% of T(T), 5% of total, sub=0

2.T3(T)=3 37.5% of T(T), 3.7% of total, sub=0

2.T1(T)=1 12.5% of T(T), 1.2% of total, sub=0

1.J(J)=6 6%* of total, sub=3(J*=3)

2.J1(J)=3 100% of J(J), 6% of total, sub=3

3.J1b(J)=2 66.7%* of J1(J), 66.7% of J(J), 4% of total, sub=0

3.J1a(J)=1 33.3%* of J1(J), 33.3% of J(J), 2% of total, sub=0

1.K(K)=5 5%* of total, sub=0

1.M1(M1)=4 4%* of total, sub=4

2.M1a(M)=2 50%* of M1(M), 2%* of total, sub=0

2.M1c(M)=1 25%* of M1(M), 1%* of total, sub=0

2.M1b1(M)=1 25%* of M1(M), 1%* of total, sub=0

1.N(N)=4 4%* of total, sub=3(N*=1)

2.N1b(N)=2 66.7% of N(N), 2.6% of total, sub=0

2.N2a(N)=1 33.5% of N(N), 1.3% of total, sub=0

1.R0a(R0a)=4 4%* of total, sub=0

1.HV(HV)=3 3%* of total, sub=0

1.HV1(HV1)=2 2%* of total, sub=0

1.X(X)=2 2%* of total, sub=0

1.W(W)=1 1%* of total, sub=0

1.A(A)=1 1%* of total, sub=0

Dead Sea(Jordan Valley) mtDNA=43

1.U(U)=20 46.5%* of total, sub=19(U*=1)

2.U3(U)=17 89.47% of U(U), 41.6% of total, sub=0

2.U1a(U)=1 5.26% of U(U), 2.447% of total, sub=0

2.U5a(U)=1 5.26% of U(U), 2.447% of total, sub=0

1.H(H)=9 21%* of total, sub=0

1.L(L)=8 18.6%* of total, sub=8

2.L3(L3)=6 75%* of L(L), 14%* of total, sub=6

3.L3b1(L3)=4 66.7%* of L3(L3), 50%* of L(L), 9.3%* of total, sub=0

3.L3f1(L3)=2 33.3%* of L3(L3), 25%* of L(L), 4.65%* of total, sub=0

2.L2a/L2c(L2)=2 25%* of L(L), 4.65%* of total, sub=0

1.HV(HV)=2 4.65%* of total, sub=0

1.HV1(HV1)=1 2.32%* of total, sub=0

1.I(I)=1 2.32%* of total, sub=0

1.J(J)=1 2.32%* of total, sub=0

1.R2(R2)=1 2.32%* of total, sub=0



Jordon-total mtDNA=290

1.H(H)=76 26%* of total, sub=0

1.U(U)=56 19.3%* of total, sub=35(U*=1)

2.U3(U)=23 65.7% of U(U), 12.7% of total, sub=0

2.U1(U)=5 14.28% of U(U), 2.76% of total, sub=5

3.U1b(U)=3 60%* of U1(U), 8.57% of U(U), 1.6% of total, sub=0

3.U1a(U)=2 40%* of U1(U), 5.7% of U(U), 1.1% of total, sub=0

2.U5(U)=2 5.7% of U(U), 1.1% of total, sub=1

3.U5a1(U)=1 100% of U(U), 5.7% of U(U), 1.1% of total, sub=0

2.U4(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U2e(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U8b/U2d(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U8b(U)=1 2.8% of U(U), 0.55% of total, sub=0

2.U9(U)=1 2.8% of U(U), 0.55% of total, sub=0

1.L(L)=29 10%* of total, sub=27(-(L01)=2)

2.L3(L3)=17 63% of L(L), 6.3% of total, sub=10

3.L3b'f(L3)=7 70% of L3(L3), 44% of L(L), 4.4% of total, sub=7

4.L3b(L3)=5 71.4%* of L3b'f(L3), 50% of L3(L3), 31.4% of L(L), 3.14% of total, sub=1

5.L3b1(L3)=1 100% of L3b(L3), 71.4% of L3b'f(L3), 50% of L3(L3), 31.4% of L(L), 3.14% of total, sub=0

4.L3f1(L3)=2 28.57%* of L3b'f(L3),20% of L3(L3), 12.6% of L(L), 1.26% of total, sub=0

3.L3e'i'k'x(L3)=2 20% of L3(L3), 12.6% of L(L), 1.26% of total, sub=2

4.L3i2(L3), former L3w=1 50%* of L3e'i'k'x(L3), 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

4.L3x2(L3), former L3w=1 50%* of L3e'i'k'x(L3), 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

3.L3d2(L2)=1 10% of L3(L3), 6.3% of L(L), 0.63% of total, sub=0

2.L2(L2)=7 26% of L(L), 2.6% of total, sub=5

3.L2a1(L2)=2 40% of L2(L2), 10.37% of L(L), 1% of total, sub=0

3.L2a/L2c(L2)=2 40% of L2(L2), 10.37% of L(L), 1% of total, sub=0

3.L2c2(L2)=1 20% of L2(L2), 5.2% of L(L), 0.52% of total, sub=0

2.L0a1(L0)=2 7.4% of L(L), sub=1

3.L0a1a(L0)=1 100% of L0a1(L0), 7.4% of L(L), sub=0

2.L1b1(L1)=1 3.7% of L(L), 0.37% of total, sub=0

1.T(T)=26 9%* of total, sub=8(T*=2)

2.T2(T)=4 50% of T(T), 4.5% of total, sub=0

2.T3(T)=3 37.5% of T(T), 3.36% of total, sub=0

2.T1(T)=1 12.5% of T(T), 1.1% of total, sub=0

1.J(J)=25 8.6%* of total, sub=4(J*=3)

2.J1(J)=4 100% of J(J), 8.6% of total, sub=3

3.J1b=2 66.7% of J1(J), 66.7% of J(J), 5.74% of total, sub=0

3.J1a(J)=1 33.3% of J1(J), 33.3% of J(J), 2.87% of total, sub=0

1.N(N)=17 5.86%* of total, sub=16(N*=1)

2.N1(N)=15 93.75% of N(N), 5.5% of total, sub=2

3.N1b=2 100% of N1(N), 93.75% of N(N), 5.5% of total, sub=0

2.N2a(N)=1 6.25% of N(N), 0.36% of total, sub=0

1.HV(HV)=16 5.5%* of total, sub=0

1.K(K)=11 3.8%* of total, sub=0

1.R0(R0)=10 3.4%* of total, sub=4

2.R0a(R0)=4 100% of R0(R0), 3.4% of total, sub=0

1.X(X)=5 1.7%* of total, sub=0

1.W(W)=4 1.38%* of total, sub=0

1.M1(M)=4 1.38%* of total, sub=4

2.M1a(M)=2 50%* of M1(M), 0.7%* of total, sub=0

2.M1b1(M)=1 25%* of M1(M), 0.3%* of total, sub=0

2.M1c(M1)=1 25%* of M1(M), 0.3%* of total, sub=0

1.I(I)=4 1.38%* of total, sub=0

1.HV1(HV1)=3 1%* of total, sub=0

1.D(D)=1 0.34%* of total, sub=0

1.A(A)=1 0.34%* of total, sub=0

1.R2(R2)=1 0.34%* of total, sub=0

1.V(V)=1 0.34%* of total, sub=0

Nairobi, Kenya mtDNA=84

1.L(L)=77 91.6%* of total, sub=77

2.L3(L3)=37 48%* of L(L), 44%* of total, sub=37

3.L3g(L3)=16 43%* of L3(L3), 20.77%* of L(L), 19%* of total, sub=0

3.L3b'f(L3)=11 29.7%* of L3(L3), 14.28%* of L(L), 13.1%* of total, sub=11

4.L3b1(L3)=6 54.5%* of L3b'f(L3), 16.2%* of L3(L3), 7.8%* of L(L), 7.14%* of total, sub=0

4.L3f(L3)=5 45.45%* of L3b'f(L3), 13.5%* of L3(L3), 6.5%* of L(L), 6%* of total, sub=3

5.L3f1(L3)=3 100% of L3f(L3), 45.45% of L3b'f(L3), 13.5% of L3(L3), 6.5% of L(L), 6% of total, sub=0

3.L3e(L3)=10 27%* of L3(L3), 13%* of L(L), 12%* of total, sub=10

4.L3e1(L3)=5 50%* of L3e(L3), 13.5%* of L3(L3), 6.5%* of L(L), 6%* of total, sub=1

5.L3e1a(L3)=1 100% of L3e1(L3), 50% of L3e(L3), 13.5% of L3(L3), 6.5% of L(L), 6% of total, sub=0

4.L3e3(L3)=3 30%* of L3e(L3), 8.1%* of L3(L3), 4%* of L(L), 3.57%* of total, sub=0

4.L3e2b(L3)=2 20%* of L3e(L3), 5.4%* of L3(L3), 2.6%* of L(L), 2.38%* of total, sub=0

2.L0a'b'f(L0)=23 30%* of L(L), 27.3%* of total, sub=23

3.L0a(L0)=15 65.2%* of L0a'b'f(L3), 19.5%* of L(L), 17.85%* total, sub=0

3.L0f(L0)=8 34.7%* of L0a'b'f(L0), 10.38%* of L(L), 9.52%* of total, sub=0

2.L2(L2)=10 13%* of L(L), 12%* of total, sub=9

3.L2a(L2)=8 89% of L2(L2), 11.5% of L(L), 10.6% of total, sub=0

3.L2d1(L2)=1 11.1% of L2(L2), 1.44% of L(L), 1.32% of total, sub=0

2.L1(L1)=4 5.2%* of L(L), 4.76%* of total, sub=4

3.L1b(L1)=2 50%* of L1(L1), 2.6%* of L(L), 2.38%* of total, sub=0

3.L1c(L1)=2 50%* of L1(L1), 2.6%* of L(L), 2.38%* of total, sub=0

2.L5 former L1e(L1)=3 4%* of L(L), 3.57%* of total, sub=0

1.M1(M)=4 4.76%* of total, sub=0

1.R0a(R0a)=1 1.2%* of total, sub=0

1.U6a(U)=1 1.2%* of total, sub=0

1.J1(J)=1 1.2%* of total, sub=0

Lebanon mtDNA=979, did not count -(-)=1

1.H(H)=293 30%* of total, sub=0, counted R0(H)=1

1.U(U)=117 12%* of total, sub=0

1.T(T)=100 10.2%* of total, sub=0

1.J(J)=92 9.4%* of total, sub=0, counted J(-)=1

1.K(K)=89 9%* of total, sub=0, counted K(-)=1

1.HV(HV)=74 7.55%* of total, sub=0

1.R0(R0)=49 5%* of total, sub=0, counted -(R0)=1

1.L(L)=21 2.14%* of total, sub=20, counted -(L01)=1

2.L3(L3)=15 75% of L(L), 1.6% of total, sub=0, counted L3(K)=1

2.L2(L2)=5 25% of L(L), 0.5% of total, sub=0

1.N(N)=44 4.5%* of total, sub=41

2.N1(N)=41 100% of N(N), 4.5% of total, sub=0, counted -(N1)=4

1.I(I)=21 2.14%* of total, sub=0

1.X(X)=18 1.83%* of total, sub=0, counted -(X)=3, X(-)=1

1.W(W)=16 1.6%* of total, sub=0

1.M(M)=14 1.4%* of total, sub=0, counted -(M)=3

1.R(R)=12 1.22%* of total, sub=0, counted R(-)=3

1.V(V)=9 0.92%* of total, sub=0

1.A(A)=4 0.408%* of total, sub=0

1.JT(JT)=3 0.306%* of total, sub=0

1.-(R9)=2 0.204%* of total, sub=0

1.D(D)=2 0.204%* of total, sub=0

Libya mtDNA=31

1.L(L)=10 32.2%* of total, sub=10

2.L3(L3)=8 80%* of L(L), 25.8%* of total, sub=0

2.L2(L2)=2 20%* of L(L), 6.45%* of total, sub=0, counted L2(-)=1

1.H(H)=8 25.8%* of total, sub=0

1.T(T)=3 9.677%* of total, sub=0

1.U(U)=3 9.677%* of total, sub=0

1.V(V)=3 9.677%* of total, sub=0

1.R0(R0)=2 6.45%* of total, sub=0

1.I(I)=1 3.22%* of total, sub=0

1.J(J)=1 3.22%* of total, sub=0

Libyan Sahara, Fezzan-Tahala mtDNA=63

1.L(L)=43 68%* of total, sub=43

2.L3(L3)=15 34.88%* of L(L), 23.8%* of total, sub=15

3.L3e'i'k'x(L3)=13 86.6%* of L3(L3), 30.2%* of L(L), 20.6%* of total, sub=13

4.L3e(L3)=10 77%* of L3e'i'k'x(L3), 66.7%* of L3(L3), 23.2%* of L(L), 15.87%* of total, sub=10

5.L3e1(L3)=4 40%* of L3e(L3), 30.76%* of L3e'i'k'x(L3), 26.7% of L3(L3), 9.3%* of L(L), 6.34%* of total, sub=0

5.L3e3(L3)=4 40%* of L3e(L3), 30.76%* of L3e'i'k'x(L3), 26.7% of L3(L3), 9.3%* of L(L), 6.34%* of total, sub=0

5.L3e2(L3)=2 20%* of L3e(L3), 15.38%* of L3e'i'k'x(L3), 13.3%* of L3(L3), 4.655* of L(L), 3.17%* of total, sub=1

6.L3e2b(L3)=1 100% of L3e2(L3), 20% of L3e9L3), 15.38% of L3e'i'k'x(L3), 13.3% of L3(L3), 4.655% of L(L), 3.17% of total, sub=0

4.L3i2(L3)=3 23%* of L3e'i'k'x(L3), 20%* of L3(L3), 7%* of L(L), 4.76%* of total, sub=0

3.L3f1b(L3)=2 13.3%* of L39L3), 4.65%* of L(L0, 3.17%* of total, sub=0

2.L2(L2)=15 34.88%* of L(L), 23.8%* of total, sub=15

3.L2a1(L2)=13 86.7%* of L2(L2), 30.2%* of L(L), 20.6%* of total, sub=1

4.L2a1a(L2)=1 100% of L2a1(L2), 86.7% of L2(L2), 30.2% of L(L), 20.6% of total, sub=0

3.L2b(L2)=2 13.3%* of L2(L2), 4.65%* of L(L), 3.17%* of total, sub=0

2.L0a1a(L0)=8 18.6%* of L(L), 12.7%* of total, sub=0

2.L1b1(L1)=5 11.6%* of L(L), 8%* of total, sub=2

3.L1b1a(L1)=2 100% of L1b1(L1), 11.6% of L(L), 8% of total, sub=0

1.H1(H)=16 25.4%* of total, sub=0

1.M1(M)=2 3.17%* of total, sub=0

1.V(V)=2 3.17%* of total, sub=0

Libyan Sahara, Fezzan-al Awaynat mtDNA=66

1.H1=63 95.4%* of total, sub=0

1.V=3 4.5%* of total, sub=0


Libyan Sahara total mtDNA=129

1.H1(H)=79 61.2%* of total, sub=0

1.L(L)=43 33.3%* of total, sub=43

2.L3(L3)=15 34.88%* of L(L), 11.6%* of total, sub=15

3.L3e'i'k'x(L3)=13 86.6%* of L3(L3), 30.2%* of L(L), 10%* of total, sub=13

4.L3e(L3)=10 77%* of L3e'i'k'x(L3), 66.7%* of L3(L3), 23.2%* of L(L), 7.75%* of total, sub=10

5.L3e1(L3)=4 40%* of L3e(L3), 30.76%* of L3e'i'k'x(L3), 26.7%* of L3(L3), 9.3%* of L(L), 3.1%* of total, sub=0

5.L3e3(L3)=4 40%* of L3e(L3), 30.76%* of L3e'i'k'x(L3), 26.7% of L3(L3), 9.3%* of L(L), 3.1%* of total, sub=0

5.L3e2(L3)=2 20%* of L3e(L3), 15.38%* of L3e'i'k'x(L3), 13.3%* of L3(L3), 4.655* of L(L), 1.5%* of total, sub=1

6.L3e2b(L3)=1 100% of L3e2(L3), 20% of L3e9L3), 15.38% of L3e'i'k'x(L3), 13.3% of L3(L3), 4.655% of L(L), 1.5% of total, sub=0

4.L3i2(L3)=3 23%* of L3e'i'k'x(L3), 20%* of L3(L3), 7%* of L(L), 2.3%* of total, sub=0

3.L3f1b(L3)=2 13.3%* of L39L3), 4.65%* of L(L0, 1.5%* of total, sub=0

2.L2(L2)=15 34.88%* of L(L), 11.6%* of total, sub=15

3.L2a1(L2)=13 86.7%* of L2(L2), 30.2%* of L(L), 10%* of total, sub=1

4.L2a1a(L2)=1 100% of L2a1(L2), 86.7% of L2(L2), 30.2% of L(L), 10% of total, sub=0

3.L2b(L2)=2 13.3%* of L2(L2), 4.65%* of L(L), 1.5%* of total, sub=0

2.L0a1a(L0)=8 18.6%* of L(L), 6.2%* of total, sub=0

2.L1b1(L1)=5 11.6%* of L(L), 3.87%* of total, sub=2

3.L1b1a(L1)=2 100% of L1b1(L1), 11.6% of L(L), 3.87% of total, sub=0

1.V(V)=5 3.87%* of total, sub=0

1.M1(M)=2 1.5%* of total, sub=0


Mali, Turag, Gossi mtDNA=21


1.H(H)=11 52.3%* of total, sub=11

2.H1(H)=10 91%* of H(H), 47.6%* of total, sub=0

2.H3*(H)=1 9%* of H(H), 4.76%* of total, sub=0

1.L(L)=6 28.57%* of total, sub=6

2.L2(L2)=4 66.7%* of L(L), 19%* of total, sub=4

3.L2a(L2)=3 75%* of L2(L2), 50%* of L(L), 14.28%* of total, sub=1

4.L2a1(L2)=1 100% of L2a(L2), 75% of L2(L2), 50% of L(L), 1.28% of total, sub=0

3.L2*(L2)=1 25%* of L2(L2), 16.7%* of L(L), 4.76%* of total, sub=0

2.L1b(L1)=2 33.3%* of L(L), 9.5%* of total, sub=1

3.L1b1(L1)=1 100% of L1b(L1), 33.3% of L(L), 9.5% of total, sub=0

1.M1b1(M)=4 19%* of total, sub=0


El-Jadida (100Km south Casablanca) mtDNA=81


1.L(L)=25 30.86%* of total, sub=25

2.L3(L3)=12 48%* of L(L), 14.8%* of total, sub=12

3.L3b'f(L3)=5 41.6%* of L3(L3), 20%* of L(L), 6.17%* of total, sub=5

4.L3f1(L3)=4 80%* of L3b'f(L3), 33.3%* of L3(L3), 16%* of L(L), 5%* of total, sub=3

5.L3f1b(L3)=2 66.7% of L3f1(L3), 53.3% of L3b'f(L3), 22.2% of L3(L3), 10.6% of L(L), 3.3% of total, sub=0

5.L3f1a(L3)=1 33.3% of L3f1(L3), 26.65% of L3b'f(L3), 11.1% of L3(L3), 5.3% of L(L), 1.65% of total, sub=0

4.L3b1(L3)=1 20%* of L3b'f, 8.3%* of L3(L3), 4%* of L(L), 1.23%* of total, sub=0

3.L3d(L3)=3 25%* of L3(L3), 12%* of L(L), 3.7%* of total, sub=2

4.L3d1'2'3(L3)=2 100% of L3d(L3), 25% of L3(L3), 12% of L(L), 3.7% of total, sub=0

3.L3e2=3 25%* of L3(L3), 12%* of L(L), 3.7%* of total, sub=3

4.L3e2a(L3)=2 66.7%* of L3e2(L3), 16.7%* of L3(L3), 8%* of L(L), 2.47%* of total, sub=0

4.L3e2b(L3)=1 33.3%* of L3e2(L3), 8.35* of L3(L3), 4%* of L(L), 1.235%* of total, sub=0

3.L3h1b(L3)=1 8.3%* of L3(L3), 4%* of L(L), 1.235* of total, sub=0

2.L2a'b'c'd(L2)=7 28%* of L(L), 8.6%* of total, sub=7

3.L2a1(L2)=5 71.4%* of L2a'b'c'd(L2), 20%* of L(L), 6.17%* of total, sub=0

3.L2c1(L2)=1 14.28%* of L2a'b'c'd(L2), 4%* of L(L), 1.23%* of total, sub=0

3.L2d1(L2)=1 14.28%* of L2a'b'c'd(L2), 4%* of L(L), 1.23%* of total, sub=0

2.L1(L1)=6 24%* of L(L), 7.4%* of total, sub=6

3.L1b1(L1)=5 83.3%* of L1(L1), 20%* of L(L), 6.17%* of total, sub=0

3.L1c4(L1)=1 16.7%* of L1(L), 4% of L(L), 1.23%* of total, sub=0

1.H(H)=14 17.3%* of total, sub=11(H*=3)

2.H1(H)=10 91% of H(H), 15.7% of total, sub=0

2.H7(H)=1 9.1% of H(H), 1.6% of total, sub=0

1.K(K)=8 9.87%* of total, sub=0

1.V(V)=8 9.87%* of total, sub=0

1.U(U)=7 8.6%* of total, sub=4

2.U6a(U)=2 50% of U(U), 4.3% of total, sub=0

2.U4(U)=1 25% of U(U), 2.15% of total, sub=0

2.U5b(U)=1 25% of U(U), 2.15% of total, sub=0

1.J(J)=6 7.4%* of total, sub=3

2.J2(J)=3 100% of J(J), 7.4% of total, sub=0

1.M1(M)=5 6.17%* of total, sub=2

2.M1a(M)=2 100% of M1(M), 6.17% of total, sub=0

1.R0a(R0a)=3 3.7%* of total, sub=0

1.T(T)=2 2.47%* of total, sub=1

2.T1(T)=1 100% of T(T), 2.47% of total, sub=0

1.HV1(HV1)=1 1.23%* of total, sub=0

1.X(X)=1 1.23%* of total, sub=0

1.N1b(N)=1 1.23%* of total, sub=0


North-Central Mooroco mtDNA=56


1.H(H)=18 32.14%* of total, sub=0

1.L(L)=15 26.78%* of total sub=15

2.L2(L2)=6 40%* of L(L), 10.7%* of total, sub=6

3.L2a1(L2)=4 66.7%* of L2(L2), 26.7%* of L(L), 7.14%* of total, sub=2

4.L2a1c(L2)=2 100% of L2a1(L2), 66.7% of L2(L2), 26.7% of L(L), 7.14% of total, sub=1

5.L2a1c1(L2)=1 100% of L2a1(L2), 66.7% of L2(L2), 26.7% of L(L), 7.14% of total, sub=0

3.L2d1(L2)=2 33.3%* of L2(L2), 13.3%* of L(L), 3.57%* of total, sub=0

2.L1(L1)=5 33.3%* of L(L), 9%* of total, sub=5

3.L1b(L1)=4 80%* of L1(L1), 26.7%* of L(L), 7.14%* of total, sub=0

3.L1c3b1(L1)=1 20%* of L1(L1), 6.7%* of L(L), 1.78%* of total, sub=0

2.L3(L3)=3 20%* of L(L), 5.3%* of total, sub=3

3.L3f(L3)=2 66.7%* of L3(L3), 13.3%* of L(L), 3.57%* of total, sub=1

4.L3f3(L3)=1 100% of L3f(L3), 66.7% of L3(L3), 13.3% of L(L), 3.57% of total, sub=0

3.L3e2(L3)=1 33.3%* of L3(L3), 6.65%* of L(L), 1.785%* of total, sub=0

2.L4(L4)=1 6.7%* of L(L), 1.78%* of total, sub=0

1.M1(M)=5 9%* of total, sub=2

2.M1a2a(M)=1 50% of M1(M), 4.46% of total, sub=0

2.M1b1a(M)=1 50% of M1(M), 4.46% of total, sub=0

1.K(K)=4 7.14%* of total, sub=0

1.U(U)=4 7.14%* of total, sub=4

2.U5b(U)=3 75%* of U(U), 5.3%* of total, sub=0

2.U6a(U)=1 25%* of U(U), 1.78%* of total, sub=0

1.J(J)=3 5.35%* of total, sub=3

2.J1c(J)=2 66.7%* of J(J), 3.57%* of total, sub=0

2.J2b(J)=1 33.3%* of J(J), 1.78* of total, sub=0

1.R0a(R0a)=2 3.57%* of total, sub=2

2.R0a1(R0a)=1 50%* of R0a(R0a), 1.78%* of total, sub=0

2.R0a2a(R0a)=1 50%* of R0a(R0a), 1.78%* of total, sub=0

1.T(T)=2 3.57%* of total, sub=2

2.T1a(T)=1 505* of T(T), 1.78%* of total, sub=0

2.T2(T)=1 505* of T(T), 1.78%* of total, sub=0

1.HV0(HV0)=1 1.78%* of total, sub=0

1.X1a(X)=1 1.78%* of total, sub=0

1.R*(R)=1 1.78%* of total, sub=0


Morocco total mtDNA=137


1.L(L)=40 29.2%* of total, sub=40

2.L3(L3)=15 37.5%* of L(L), 11%* of total, sub=15

3.L3b'f(L3)=7 46.7%* of L3(L3), 17.5%* of L(L), 5.1%* of total, sub=7

4.L3f(L3)=6 85.7%* of L3b'f(L3), 40%* of L3(L3), 15%* of L(L), 4.38%* of total, sub=5

5.L3f1(L3)=4 80% of L3f(L3), 68.57% of L3b'f(L3), 32% of L3(L3), 12% of L(L), 3.5% of total, sub=3

6.L3f1b(L3)=2 66.7% of L3f1(L3), 53.3% of L3f(L3), 45.7% of L3b'f(L3), 21.3% of L3(L3), 8% of L(L), 2.33% of total, sub=0

6.L3f1a=1 33.3% of L3f1(L3), 26.65% of L3f(L3), 22.85% of L3b'f(L3), 10.65% of L3(L3), 4% of L(L), 1.165% of total, sub=0

4.L3b1(L3)=1 14.28%* of L3b'f(L3), 6.7%* of L3(L3), 2.5%* of L(L), 0.73% of total, sub=0

3.L3e2(L3)=4 26.7%* of L3(L3), 10%* of L(L), 3%* of total, sub=3

4.L3e2a(L3)=2 66.7% of L3e2(L3), 1.7% of L3(L3), 6.7% of L(L), 2% of total, sub=0

4.L3e2b(L3)=1 33.3% of L3e2(L3), 8.5% of L3(L3), 3.35% of L(L), 1% of total, sub=0

3.L3d(L3)=3 20%* of L3(L3), 7.5%* of L(L), 2.9%* of total, sub=2

4.L3d1'2'3(L3)=2 100% of L3d(L3), 20% of L3(L3), 7.5% of L(L), 2.9% of total, sub=0

3.L3h1b(L3)=1 6.7%* of L3(L3), 2.5%* of L(L), 0.7%* of total, sub=0

2.L2(L2)=13 32.5%* of L(L), 9.5%* of total, sub=13

3.L2a1(L2)=9 69%* of L2(L2), 22.5%* of L(L), 6.56%* of total, sub=2

4.L2a1c(L2)=2 100% of L2a1(L2), 69% of L2(L2), 22.5% of L(L), 6.56% of total, sub=1

5.L2a1c1=1 100% of L2a1c(L2), 100% of L2a1(L2), 69% of L2(L2), 22.5% of L(L), 6.56% of total, sub=0

3.L2d1(L2)=3 23%* of L2(L2), 7.5%* of L(L), 2.2%* of total, sub=0

3.L2c1(L2)=1 7.7%* of L2(L2), 2.5%* of L(L), 0.73%* of total, sub=0

2.L1(L1)=11 27.5%* of L(L), 8%* of total, sub=11

3.L1b(L1)=9 81.8%* of L1(L1), 22.5%* of L(L), 6.56%* of total, sub=5

4.L1b1(L1)=5 100% of L1b(L1), 81.8% of L1(L1), 22.5% of L(L), 6.56% of total, sub=0

3.L1c(L1)=2 18.2%* of L1(L1), 5%* of L(L), 1.45%* of total, sub=2

4.L1c4(L1)=1 50%* of L1c(L1), 9.1%* of L1(L1), 2.5%* of L(L), 0.73%* of total, sub=0

4.L1c3b1(L1)=1 50%* of L1c(L1), 9.1%* of L1(L1), 2.5%* of L(L), 0.73%* of total, sub=0

2.L4(L4)=1 2.5%* of L(L), 0.78%* of total, sub=0

1.H(H)=32 23.35%* of total, sub=11

2.H1(H)=10 91% of H(H), 21% of total, sub=0

2.H7(H)=1 9.1% of H(H), 2.1% of total, sub=0

1.K(K)=12 8.75%* of total, sub=0

1.U(U)=11 8%* of total, sub=8

2.U5b(U)=4 50% of U(U), 4% of total, sub=0

2.U6a(U)=3 37.5% of U(U), 3% of total, sub=0

2.U4(U)=1 12.5% of U(U), 1% of total, sub=0

1.M1(M)=10 7.3%* of total, sub=4

2.M1a(M)=3 75% of M1(M), 5.46% of total, sub=1

3.M1a2a(M)=1 100% of M1a(M), 75% of M1(M), 5.46% of total, sub=0

2.M1b1a(M)=1 25% of M1(M), 1.8% of total, sub=0

1.J(J)=9 6.56%* of total, sub=6

2.J2(J)=4 66.7% of J(J), 4.37% of total, sub=1

3.J2b(J)=1 100% of J2(J), 66.7% of J(J), 4.37% of total, sub=0

2.J1c(J)=2 33.3% of J(J), 2.2% of total, sub=0

1.V(V)=8 5.8%* of total, sub=0

1.R0a(R0a)=5 3.64%* of total, sub=2

2.R0a1(R0)=1 50% of R0a(R0a), 1.8% of total, sub=0

2.R0a2a(R0)=1 50% of R0a(R0a), 1.8% of total, sub=0

1.T(T)=4 3%* of total, sub=3

2.T1(T)=2 66.7% of T(T), 2% of total, sub=1

3.T1a(T)=1 100% of T1(T), 66.7% of T(T), 2% of total, sub=0

2.T2(T)=1 33.3% of T(T), 1% of total, sub=0

1.X(X)=2 1.45%* of total, sub=1

2.X1a(X)=1 100% of X(X), 1.45% of total, sub=0

1.HV1(HV1)=1 1%* of total, sub=0

1.HV0(HV0)=1 1%* of total, sub=0

1.N1b(N)=1 1%* of total, sub=0

1.R*(R)=1 1%* of total, sub=0

Niger, Turag, Tanut mtDNA=25

1.L(L)=19 76%* of total, sub=19

2.L3(L3)=8 42%* of L(L), 32%* of total, sub=7

3.L3b(L3)=2 28.57%* of L3(L3), 12%* of L(L), 9.14%* of total, sub=0

3.L3d(L3)=2 28.57%* of L3(L3), 12%* of L(L), 9.14%* of total, sub=0

3.L3f1(L3)=2 28.57%* of L3(L3), 12%* of L(L), 9.14%* of total, sub=0

3.L3h(L3)=1 14.3%* of L3(L3), 6%* of L(L), 4.57%* of total, sub=0

2.L2a(L2)=6 31.57%* of L(L), 4.37%* of total, sub=3

3.L2a1(L2)=3 100% of L2a(L2), 31.57% of L(L), 4.37% of total, sub=0

2.L1(L1)=4 21%* of L(L), 16%* of total, sub=4

3.L1b1(L1)=3 75%* of L1(L1), 15.78%* of L(L), 12%* of total, sub=0

3.L1c(L1)=1 25%* of L1(L), 5.26%* of L(L), 4%* of total, sub=0

2.L0a1a(L0)=1 5.26%* of L(L), 4%* of total, sub=0

1.V(V)=3 12%* of total, sub=0

1.H1(H)=1 5.26%* of total, sub=0

1.U3a(U)=1 5.26%* of total, sub=0

1.M1b2(M)=1 5.26%* of total, sub=0

Palestinians mtDNA=120

1.H(H)=30 25%* of total, sub=0

1.J(J)=18 15%* of total, sub=0

1.T(T)=15 12.5%* of total, sub=0

1.U(U)=12 10%* of total, sub=0

1.HV(HV)=10 8.3%* of total, sub=0

1.L(L)=9 7.5%* of total, sub=9

2.L2(L2)=6 66.7%* of L(L), 5%* of total, sub=0

2.L3(L3)=3 33.3%* of total, 2.5%* of total, sub=0

1.R0(R0)=7 5.8%* of total, sub=0

1.K(K)=5 4.16%* of total, sub=0

1.X(X)=5 4.16%* of total, sub=0

1.M(M)=4 3.3%* of total, sub=0

1.N(N)=3 2.5%* of total, sub=1

2.N1(N)=1 100% of N(N), 2.5% of total, sub=0

1.I(I)=1 0.83%* of total, sub=0

1.W(W)=1 0.83%* of total, sub=0

Saudi Arabia mtDNA=539

1.J(J)=116 21.5%* of total, sub=85(J*=28, J2/J1d=3

2.J1(J)=85 100% of J(J), 21.5% of total, sub=71

3.J1b=52 73% of J1(J), 73% of J(J), 15.76% of total, sub=0

3.J1d(J1)=18 25.3% of J1(J), 25.3% of J(J), 5.4% of total, sub=0

3.J1a(J)=1 1,4% of J1(J), 1.4% of J(J), 0.3% of total, sub=0

1.R0a(R0)=98 18.2%* of total, sub=98

2.R0a1(R0)=58 59.2%* of R0a(R0), 10.76%* of total, sub=58

3.R0a1a(R0)=47 81%* of R0a1(R0), 48%* of R0a(R0), 8.72%* of total, sub=0

3.R0a1*(R0)=11 19%* of R0a1(R0), 11.2%* of R0a(R0), 2%* of total, sub=0

2.R0a2(R0)=40 40.8%* of R0a(R0), 7.4%* of total, sub=0

1.U(U)=59 11%* of total, sub=55

2.U9a(U)=13 23.6% of U(U), 2.58% of total, sub=0

2.U3(U)=13 23.6% of U(U), 2.58% of total, sub=0

2.U1(U)=6 11% of U(U), 1.2% of total, sub=6

3.U1a(U)=5 83.3%* of U1(U), 9.1% of U(U), 1% of total, sub=0

3.U1b(U)=1 16.7%* of U1(U), 1.8% of U(U), 0.2% of total, sub=0

2.U4(U)=5 9.1% of U(U), 1% of total, sub=0

2.U6(U)=5 9.1% of U(U), 1% of total, sub=5

3.U6a(U)=3 60%* of U6(U), 5.4% of U(U), 0.6% of total, sub=2

4.U6a1(U)=2 100% of U6a(U), 60% of U6(U), 5.4% of U(U), 0.6% of total, sub=0

3.U6b(U)=2 40%* of U6(U), 3.6% of U(U), 0.4% of total, sub=0

2.U7(U)=4 7.27% of U(U), 0.8% of total, sub=0

2.U2e(U)=4 7.27% of U(U), 0.8% of total, sub=0

2.U5(U)=4 7.27% of U(U), 0.8% of total, sub=2

3.U5a1a(U)=2 100% of U5(U), 7.27% of U(U), 0.8% of total, sub=0

2.U8b/U2d(U)=3 5.45% of U(U), 0.6% of total, sub=0

1.L(L)=54 10%* of total, sub=54

2.L3(L3)=19 35.18%* of L(L), 3.5%* of total, sub=18(L3*=1)

3.L3x(L3)=4 22.2% of L3(L3), 7.8% of L(L), 0.78% of total, sub=4

4.L3x1(L3)=2 50%* of L3x(L3), 11.1% of L3(L3), 4% of L(L), 0.4% of L(L), sub=0

4.L3x2(L3)=2 50%* of L3x(L3), 11.1% of L3(L3), 4% of L(L), 0.4% of L(L), sub=0

3.L3f(L3)=4 22.2% of L3(L3), 7.8% of L(L), 0.78% of total, sub=3

4.L3f1(L3)=3 100% of L3f(L3), 22.2% of L3(L3), 7.8% of L(L), 0.78% of total, sub=0

3.L3d(L3)=3 16.7% of L3(L3), 5.8% of L(L), 0.58% of total, sub=3

4.L3d1(L3)=2 66.7%* of L3d(L3), 11.1% of L3(L3), 4% of L(L), 0.4% of total, sub=0

4.L3d3(L3)=1 33.3%* of L3d(L3), 5.55 of L3(L3), 2% of L(L), 0.2% of total, sub=0

3.L3b(L3)=3 16.7% of L3(L3), 5.8% of L(L), 0.58% of total, sub=1

4.L3b1(L3)=1 100% of L3b(L3), 16.7% of L3(L3), 5.8% of L(L), 0.58% of total, sub=0

3.L3i(L3)=2 11.1% of L3(L3), 4% of L(L), 0.4% of total, sub=1

4.L3i2(L3) former L3w=1 100% of L3i(L3), 11.1% of L3(L3), 4% of L(L), 0.4% of total, sub=0

3.L3h1(L3)=2 11.1% of L3(L3), 4% of L(L), 0.4% of total, sub=1

2.L2(L2)=19 35%* of L(L), 3.5%* of total, sub=19

3.L2a(L2)=17 89.47%* of L2(L2), 31.48%* of L(L), 3.15%* of total, sub=15

4.L2a1(L2)=12 80% of L2a(L2), 71.5% of L2(L2), 25.2% of L(L), 2.5% of total, sub=2(L2a1beta3=1)

5.L2a1a=2 100% of L2a1(L2), 80% of L2a(L2), 71.5% of L2(L2), 25.2% of L(L), 2.5% of total, sub=0

4.L2a2(L2)=3 20% of L2a(l2), 18% of L2(L2), 6.3% of L(L), 0.63% of total, sub=0

3.L2b1(L2)=1 5.26% of L2(L2), 1.85% of L(L), 0.18% of total, sub=0

3.L2c2(L2)=1 5.26% of L2(L2), 1.85% of L(L), 0.18% of total, sub=0

2.L0a(L0)=6 11.1%* of L(L), 1.1%* of total, sub=3

3.L0a1(L0)=3 100% of L0a(L0), 11.1% of L(L), 1.1% of total, sub=0

2.L5a1(L5)=4 7.4%* of L(L), 0.74%* of total, sub=0

2.L1(L1)=3 5.5%* of L(L), 0.55%* of total, sub=3

3.L1c=2 66.7%* of L1(L1), 3.7%* of L(L), 0.37%* of total, sub=2

4.L1c2=1 50%* of L1c(L1), 33.3%* of L1(L1), 1.85%* of L(L), 0.185%* of total, sub=0

4.L1c3a1=1 50%* of L1c(L1), 33.3%* of L1(L1), 1.85%* of L(L), 0.185%* of total, sub=0

3.L1b1(L1)=1 33.35* of L1(L1), 1.85%* of L(L), 0.185%* of total, sub=0

3.L4a1(L4)=1 1.85%* of L(L), 0.185%* of total, sub=0

3.L6(L6)=1 1.85%* of L(L), 0.185%* of total, sub=0

3.L7(L7)=1 1.85%* of L(L), 0.185%* of total, sub=0

1.H(H)=47 8.7%* of total, sub=21

2.H2a1(H)=12 57.14% of H(H), 5% of total, sub=0

2.H6(H)=8 38.1% of H(H), 3.3% of total, sub=0

2.H20(H)=1 5% of H(H), 0.435% of total, sub=0

1.N(N)=40 7.4%* of total, sub=39(N*=1)

2.N1(N)=39 100% of N(N), 7.4% of total, sub=39

3.N1c(N)=14 36%* of N1(N), 36% of N(N), 2.66% of total, sub=0

3.N1a(N)=13 33.3%* of N1(N), 33.3% of N(N), 2.47% of total, sub=0

3.N1b(N)=12 30.77%* of N1(N), 30.77% of N(N), 2.28% of total, sub=0

1.M(M)=33 6.1%* of total, sub=32(M*=1)

2.M1=19 58.375% of M(M), 3.6% of total, sub=9

3.M1a(M)=9 100% of M1(M), 58.375% of M(M), 3.6% of total, sub=0

2.M3(M)=3 9.375% of M(M), 0.574% of total, sub=0

2.M4b(M)=2 6.25% of M(M), 0.38% of total, sub=0

2.M30(M)=2 6.25% of M(M), 0.38% of total, sub=0

2.M36a(M)=2 6.25% of M(M), 0.38% of total, sub=0

2.M33a(M)=1 3.125% of M(M), 0.19% of total, sub=0

2.M14(M)=1 3.125% of M(M), 0.19% of total, sub=0

2.M48(M)=1 3.125% of M(M), 0.19% of total, sub=0

2.M25(M)=1 3.125% of M(M), 0.19% of total, sub=0

1.T(T)=34 6.3%* of total, sub=32

2.T3(T)=13 40.6% of T(T), 2.56% of total, sub=0

2.T1(T)=12 37.5% of T(T), 2.36% of total, sub=0

2.T5(T)=6 18.75% of T(T), 1.18% of total, sub=0

2.T2(T)=1 3.125% of T(T), 0.2% of total, sub=0

1.K(K)=22 4%* of total, sub=0

1.X2(X)=15 2.78%* of total, sub=0

1.W(W)=6 1.1%* of total, sub=0

1.I(I)=5 1%* of total, sub=0

1.HV1(HV1)=4 0.745* of total, sub=0

1.Q1(Q)=4 0.745* of total, sub=0

1.R2(R)=1 0.2%* of total, sub=0

1.G2a1a(G)=1 0.2%* of total, sub=0

Saudi Arabia central Region mtDNA=266

1.R0a(R0a)=60 22.5%* of total, sub=60

2.R0a1(R0)=31 51.67%* of R0a(R0a), 11.6%* of total, sub=31

3.R0a1a1(R0)=27 8.7%* of R0a1(R0), 45%* of R0a(R0a), 10.1%* of total, sub=0

3.R0a1(R0)=4 13%* of R0a1(R0a0, 6.7%* of R0a(R0a), 1.5%* of total, sub=0

2.R0a2(R0)=29 48.3%* of R0a(R0a), 11%* of total, sub=0

1.J(J)=52 19.5%* of total, sub=37(J2/J1d=1, J*=14)

2.J1(J)=37 100% of J(J), 19.5% of total, sub=35

3.J1b(J)=20 57.14% of J1(J), 5.714% of J(J), 11% of total, sub=0

3.J1d(J)=15 42.8% of J1(J), 42.8% of J(J), 8.37% of total, sub=0

1.L(L)=31 11.6%* of total, sub=31

2.L3(L3)=12 38.7%* of L(L), 4.5%* of total, sub=11(L3*=1)

3.L3x(L3)=4 36.36% of L3(L3), 14% of L(L), 1.645 of total, sub=4

4.L3x1(L3)=2 50%* of L3x(L3), 18.18% of L3(L3), 7% of L(L), 0.8% of total, sub=0

4.L3x2(L3)=2 50%* of L3x(L3), 18.18% of L3(L3), 7% of L(L), 0.8% of total, sub=0

3.L3b(L3)=2 18.18% of L3(L3), 7% of L(L), 0.82% of total, sub=1

4.L3b1(L3)=1 100% of L3b(L3), 18.18% of L3(L3), 7% of L(L), 0.82% of total, sub=0

3.L3f(L3)=2 18.18% of L3(L3), 7% of L(L), 0.82% of total, sub=1

4.L3f1(L3)=1 100% of L3b(L3), 18.18% of L3(L3), 7% of L(L), 0.82% of total, sub=0

3.L3h1(L3)=2 18.18% of L3(L3), 7% of L(L), 0.82% of total, sub=1

3.L3i2 former L3w(L3)=1 9.1% of L3(L3), 3.5% of L(L), 0.41% of total, sub=0

2.L2a(L2)=11 35.48%* of L(L), 4.1%* of total, sub=11

3.L2a1(L2)=10 90.1%* of L2a(L2), 32.25%* of L(L), 3.76%* of total, sub=0(L2a1beta3=1)

3.L2a2(L2)=1 9.1%* of L2a(L2), 3.2%* of L(L), 0.37%* of total, sub=0

2.L0a(L0)=4 13%* of L(L), 1.5%* of total, sub=3

3.L0a1(L0)=3 100% of L0a(L0), 13% of L(L), 1.5% of total, sub=0

2.L1b1(L1)=1 3.22%* of L(L), 0.37%* of total, sub=0

2.L5a1(L5)=1 3.22%* of L(L), 0.37%* of total, sub=0

2.L6(L6)=1 3.22%* of L(L), 0.37%* of total, sub=0

2.L7(L7)=1 3.22%* of L(L), 0.37%* of total, sub=0

1.H(H)=27 10.155* of total, sub=10

2.H6(H)=5 50% of H(H), 5% of total, sub=0

2.H2a1(H)=4 40% of H(H), 4.06% of total, sub=0

2.H20(H)=1 10% of H(H), 1% of total, sub=0

1.U(U)=26 9.77%* of total, sub=24

2.U9a(U)=9 37.5% of U(U), 3.66% of total, sub=0

2.U3(U)=6 25% of U(U), 2.44% of total, sub=0

2.U6(U)=2 8.35 of U(U), 0.8% of total, sub=2

3.U6a1(U)=1 50%* of U6(U), 4.16% of U(U), 0.4% of total, sub=0

3.U6b(U)=1 50%* of U6(U), 4.16% of U(U), 0.4% of total, sub=0

2.U5(U)=2 8.35 of U(U), 0.8% of total, sub=2

3.U5a1a(U)=1 100%* of U6(U), 8.35% of U(U), 0.8% of total, sub=0

2.U1(U)=2 8.35 of U(U), 0.8% of total, sub=2

3.U1b(U)=1 50%* of U6(U), 4.16% of U(U), 0.4% of total, sub=0

3.U1a(U)=1 50%* of U6(U), 4.16% of U(U), 0.4% of total, sub=0

2.U4(U)=1 4.167% of U(U), 0.4% of total, sub=0

2.U7(U)=1 4.167% of U(U), 0.4% of total, sub=0

2.U2e(U)=1 4.167% of U(U), 0.4% of total, sub=0

1.N(N)=19 7.145* of total, sub=18(N*=1)

2.N1(N)=18 100% of N(N), 7.145% of total, sub=18

3.N1a(N)=9 50%* of N1(N), 50% of N(N), 3.57% of total, sub=0

3.N1b(N)=5 27.8%* of N1(N), 27.8% of N(N), 2% of total, sub=0

3.N1c(N)=4 22.2%* of N1(N), 22.2% of N(N), 1.587% of total, sub=0

2.M(M)=18 6.76%* of total, sub=17(M*=1)

3.M1(M)=9 53% of M(M), 3.58% of total, sub=3

4.M1a(M)=3 100% of M1(M), 53% of M(M), 3.58% of total, sub=0

2.M36a(M)=3 17.64% of M(M), 1.2% of total, sub=0

2.M30(M)=2 11.7% of M(M), 0.8% of total, sub=0

2.M3(M)=1 5.85% of M(M), 0.4% of total, sub=0

2.M48(M)=1 5.85% of M(M), 0.4% of total, sub=0

2.M14(M)=1 5.85% of M(M), 0.4% of total, sub=0

1.K(K)=15 5.63%* of total, sub=0

1.T(T)=11 4.1%* of total, sub=10

2.T3(T)=9 90% of T(T), 3.7% of total, sub=0

2.T1(T)=1 10% of T(T), 0.4% of total, sub=0

1.X2(X)=9 3.3858 of total, sub=0

1.W(W)=4 1.5%* of total, sub=0

1.I(I)=2 0.75%* of total, sub=0

1.HV1(HV1)=2 0.75%* of total, sub=0

1.G2a1a(G)=1 0.375%* of total, sub=0

1.Q1(Q)=1 0.375%* of total, sub=0

Saudi Arabia Northern region mtDNA=42

1.R0a(R0)=8 19%* of total, sub=8

2.R0a1(R0)=6 75%* of R0a(R0a), 14.28%* of total, sub=6

3.R0a1a(R0a)=5 8.3%* of R0a1(R0a1), 62.5%* of R0a(R0a), 12%* of total, sub=0

3.R0a1*(R0a)=1 16.7%* of R0a1(R0), 12.5%* of R0a(R0), 2.38%* of total, sub=0

2.R0a2(R0a)=2 25%* of R0a(R0a), 4.76%* of total, sub=0

1.J(J)=7 16.7%* of total, sub=6(J*=1)

2.J1(J)=6 100% of J(J), 16.7% of total, sub=5

3.J1b(J1)=4 80% of J1(J), 80% of J(J), 13.3% of total, sub=0

3.J1d(J)=1 20% of J1(J), 20% of J(J), 3.325% of total, sub=0

1.L(L)=5 12%* of total, sub=5

2.L2(L2)=3 60%* of L(L), 71.4%* of total, sub=3

3.L2a(L2)=2 66.7%* of L2(L2), 40%* of L(L), 4.76%* of total, sub=2

4.L2a1a(L2)=1 50%* of L2a(L2), 33.3%* of L2(L2), 20%* of L(L), 2.38%* of total, sub=0

4.L2a2(L2)=1 50%* of L2a(L2), 33.3%* of L2(L2), 20%* of L(L), 2.38%* of total, sub=0

3.L2c2(L2)=1 33.3%* of L2(L2), 20%* of L(L), 2.38%* of total, sub=0

2.L3b1(L3)=1 20%* of L(L), 2.38%* of total, sub=0

2.L5a1(L5)=1 20%* of L(L), 2.38%* of total, sub=0

1.T(T)=5 12%* of total, sub=5

2.T5(T)=3 60%* of T(T), 7.14%* of total, sub=0

2.T1(T)=2 40%* of T(T), 4.76%* of total, sub=0

1.U(U)=5 12%* of total, sub=5

2.U1a(U)=1 20%* of U(U), 2.38%* of total, sub=0

2.U2e(U)=1 20%* of U(U), 2.38%* of total, sub=0

2.U3(U)=1 20%* of U(U), 2.38%* of total, sub=0

2.U7(U)=1 20%* of U(U), 2.38%* of total, sub=0

2.U9a(U)=1 20%* of U(U), 2.38%* of total, sub=0

1.N1c(N)=4 9.5%* of total, sub=0

1.H(H)=4 9.5%* of total, sub=1

2.H6(H)=1 100% of H(H), 9.5% of total, sub=0

1.M3(M)=1 2.38%* of total, sub=0

1.K(K)=1 2.38%* of total, sub=0

1.W(W)=1 2.38%* of total, sub=0

1.X2(X)=1 2.38%* of total, sub=0

Saudi Arabia, Southern Region mtDNA=106

1.J(J)=29 27.38%* of total, sub=23(J*=6)

2.J1(J)=23 100% of J(J), 27.38% of total, sub=18

3.J1b=17 94.4% of J1(J), 94.4% of J(J), 25.8% of total, sub=0

3.J1d(J)=1 5.5% of J1(J), 5.5% of J(J), 1.5% of total, sub=0

1.R0a(R0a)=16 15.1%* of total, sub=16

2.R0a1(R0a)=11 68.75%* of R0a(R0a), 10.37%* of total, sub=11

3.R0a1a(R0a)=9 81.8%* of R0a1(R0a), 56.25%* of R0a(R0a), 8.5%* of total, sub=0

3.R0a1*(R0a)=2 18.2%* of R0a1(R0a), 12.5%* of R0a(R0a), 1.88%* of total, sub=0

2.R0a2(R0a)=5 31.25%* of R0a(R0a), 47.17%* of total, sub=0

1.U(U)=14 13.2%* of total, sub=13

2.U3(U)=4 30.76% of U(U), 4% of total, sub=0

2.U4(U)=2 15.4% of U(U), 2% of total, sub=0

2.U6(U)=2 15.4% of U(U), 2% of total, sub=2

3.U6a(U)=1 50%* of U6(U), 7.7% of U(U), 1% of total, sub=0

3.U6b(U)=1 50%* of U6(U), 7.7% of U(U), 1% of total, sub=0

2.U2e(U)=1 7.7% of U(U), 1% of total, sub=0

2.U2d/U8b(U)=1 7.7% of U(U), 1% of total, sub=0

2.U5a1a(U)=1 7.7% of U(U), 1% of total, sub=0

2.U7(U)=1 7.7% of U(U), 1% of total, sub=0

2.U9a(U)=1 7.7% of U(U), 1% of total, sub=0

1.H(H)=9 8.5%* of total, sub=7

2.H2a1(H)=5 71.4% of H(H), 6% of total, sub=0

2.H6(H)=2 28.57% of H(H), 2.4% of total, sub=0

1.N1(N)=8 7.5%* of total, sub=8

2.N1c(N)=4 50%* of N1(N), 3.77%* of total, sub-0

2.N1b(N)=3 37.5%* of N1(N), 2.8%* of total, sub=0

2.N1a(N)=1 12.5%* of N(N), 1% of total, sub=0

1.M(M)=7 6.6%* of total, sub=7

2.M1(M)=4 57%* of M(M), 3.77%* of total, sub=1

3.M1a(M)=1 100% of M1(M), 57% of M(M), 3.77% of total, sub=0

2.M4b(M)=2 28.5%* of M(M), 1.9%* of total, sub=0

2.M3(M)=1 14.25%* of M(M), 0.95%* of total, sub=0

1.L(L)=7 6.6%* of total, sub=7

2.L2(L2)=4 57%* of L(L), 3.77%* of total, sub=4

3.L2a(L2)=3 75%* of L2(L2), 42.8%* of L(L), 2.8%* of total, sub=2

4.L2a1a(L2)=1 50% of L2a(L2), 37.5% of L2(L), 21.4% of L(L), 1.4% of total, sub=0

4.L2a2(L2)=1 50% of L2a(L2), 37.5% of L2(L), 21.4% of L(L), 1.4% of total, sub=0

3.L2b1(L2)=1 25%* of L2(L2), 14.28%* of L(L), 1%* of total, sub=0

2.L3(L3)=2 28.57%* of L(L), 1.88%* of total, sub=2

3.L3f1(L3)=1 50%* of L3(L3), 14.28%* of L(L), 1%* of total, sub=0

3.L3i(L3)=1 50%* of L3(L3), 14.28%* of L(L), 1%* of total, sub=0

2.L4a1(L4)=1 14.28%* of L(L), 1%* of L(L), sub=0

1.T(T)=6 5.66%* of total, sub=5

2.T1(T)=3 60% of T(T), 3.4% of total, sub=0

2.T3(T)=2 40% of T(T), 2.26% of total, sub=0

1.K(K)=3 2.8%* of total, sub=0

1.I(I)=2 1.88%* of total, sub=0

1.HV1(HV1)=1 1%* of total, sub=0

1.W(W)=1 1%* of total, sub=0

1.X2(X)=1 1%* of total, sub=0

1.Q1(Q)=1 1%* of total, sub=0

1.R2(R)=1 1%* of total, sub=0

Saudi Arabia, Western region mtDNA=71

1.J(J)=27 38%* of total, sub=20(J*=5, J2/J1d=2)

2.J1(J)=20 100% of J(J), 38% of total, sub=14

3.J1b(J)=11 78.57% of J1(J), 78.5% of J(J), 30% of total, sub=0

3.J1d(J)=2 14.28% of J1(J), 14.28% of J(J), 5.4% of total, sub=0

3.J1a(J)=1 7.14% of J1(J), 7.14% of J(J), 2.7% of total, sub=0

1.T(T)=9 12.67%* of total, sub=9

2.T1(T)=5 55.6%* of T(T), 7%* of total, sub=0

2.T5(T)=2 22.2%* of T(T), 2.8%* of total, sub=0

2. T2(T)=1 11.1%* of T(T), 1.4%* of total, sub=0

2. T3(T)=1 11.1%* of T(T), 1.4%* of total, sub=0

1.R0a(R0a)=6 8.45%* of total, sub=6

2.R0a1(R0a)=4 66.7%* of R0a1(R0a), 5.6%* of total, sub=4

3.R0a1a(R0a)=3 75%* of R0a(R0a), 5%* of R0a(R0a), 4.22%* of total, sub=0

3.R0a1*(R0a)=1 25%* of R0a1(R0a), 16.7%* of R0a(R0a), 1.4%* of total, sub=0

2.R0a2(R0a)=2 33.%* of R0a(R0a), 2.8%* of total, sub=0

1.U(U)=6 8.45%* of total, sub=6

2.U9a(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

2.U3(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

2.U2e(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

2.U1a(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

2.U7(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

2.U6a1(U)=1 16.7%* of U(U), 1.4%* of total, sub=0

1.M1(M)=5 7%* of total, sub=4

2.M1a(M)=4 100% of M1(M), 7% of total, sub=0

1.L(L)=5 7%* of total, sub=5

2.L5a1(L5)=2 40%* of L(L), 28.16%* of total, sub=0

2.L0a(L0)=2 40%* of L(L), 28.16%* of total, sub=0

2.L3f1(L3)=1 20%* of L(L), 14.08%* of total, sub=0

1.X2(X)=4 5.6%* of total, sub=0

1.N1(N)=3 4.22%* of total, sub=3

2.N1b(N)=2 66.7%* of N1(N), 2.8%* of total, sub=0

2.N1a(N)=1 33.3%* of N1(N), 1.4%* of total, sub=0

1.K(K)=2 2.8%* of total, sub=0

1.Q1(Q)=2 2.8%* of total, sub=0

1.H2a1(H)=2 2.8%* of total, sub=0


Saudi Arabia, Eastern region mtDNA=4

1.U(U)=3 75%* of total, sub=3

2.U1a(U)=2 66.7%* of U(U), 50%* of total, sub=0

2.U8b/U2d(U)=1 33.3%* of U(U), 25%* of total, sub=0

1.L3d3(L3)=1 25%* of total, sub=0

Are these all modern mtdna results? What is the point to posting them here?

Are these all modern mtdna results? What is the point to posting them here?

Yes this is all modern mtDNA. The reason i post them here is I have no where else to put them where there is a low chance they will be erased. Eventually i will make a thread with all 5174(!!!!) samples organized. Every(or at least most) study on modern mtDNA and Y DNA will have downloadable data with tons of samples, that's where Maciamo mainly gets his data from.

Slovakia, East mtDNA=133

1.H(H)=66 49.6%* of total, sub=48(H*=18)

2.H1(H)=23 48% of H(H), 23.77% of total, sub=10

3.H1b(H)=6 60% of H1(H), 28.75% of H(H), 14.26% of total, sub=0

3.H1a(H)=4 40% of H1(H), 19.17% of H(H), 9.5% of total, sub=0

2.H5(H)=7 14.58% of H(H), 7.2% of total, sub=6

3.H5a(H)=6 100% of H5(H), 14.58% of H(H), 7.2% of total, sub=0

2.H6(H)=6 12.55 of H(H), 6.2% of total, sub=0

2.H7(H)=4 8.33% of H(H), 4.1% of total, sub=0

2.H11a(H)=3 6.25% of H(H), 3.1% of total, sub=0

2.H4(H)=2 4.16% of H(H), 2% of total, sub=0

2.H2(H)=3 6.25% of H(H), 3.1% of total, sub=1

3.H2a(H)=1 100% of H2(H), 6.25% of H(H), 3.1% of total, sub=0

1.U(U)=20 15%* of total, sub=20

2.U5(U)=10 50%* of U(U), 7.5%* of total, sub=10

3.U5b(U)=8 80%* of U5(U), 40%* of U(U), 6%* of total, sub=0

3.U5a(U)=2 20%* of U5(U), 10%* of U(U), 1.5%* of total, sub=0

2.U4(U)=8 40%* of U(U), 6%* of total, sub=5

3.U4a(U)=5 100% of U4(U), 40% of U(U), 6% of total, sub=0

2.U2(U)=1 5%* of U(U), 0.75%* of total, sub=0

2.U7(U)=1 5%* of U(U), 0.75%* of total, sub=0

1.T(T)=12 9%* of total, sub=3

2.T1(T)=3 100% of T(T), 9% of total, sub=0

1.J1(J)=10 7.5%* of total, sub=10

2.J1c(J)=6 60%* of J1(J), 4.5%* of total, sub=0

2.J1a(J)=4 40%* of J1(J), 3%* of total, sub=0

1.I(I)=8 6%* of total, sub=7

2.I1(I)=6 85.7% of I(I), 5.15% of total, sub=0

2.I3(I)=1 14.28% of I(I), 0.86% of total, sub=0

1.HV0(HV0)=7 5.26%* of total, sub=0

1.K(K)=3 2.25%* of total, sub=0

1.L2a(L2)=2 1.5%* of total, sub=0

1.M(L2)=2 1.5%* of total, sub=2

2.M1b1a(M)=1 50%* of M(M), 0.75%* of total, sub=0

2.M35b(M)=1 50%* of M(M), 0.75%* of total, sub=0

1.X(X)=2 1.5%* of total, sub=0

1.W(W)=1 0.75%* of total, sub=0

Slovakia, west mtDNA=67

1.H(H)=28 41.8%* of total, sub=21(H*=7)

2.H1(H)10 47.6% of H(H), 20% of total, sub=2

3.H1a(H)=1 50% of H1(H), 23.8% of H(H), 10% of total, sub=0

3.H1b(H)=1 50% of H1(H), 23.8% of H(H), 10% of total, sub=0

2.H5(H)=5 23.8% of H(H), 10% of total, sub=3

3.H5a(H)=3 100% of H5(H), 23.8% of H(H), 10% of total, sub=0

2.H6(H)=2 9.5% of H(H), 4% of total, sub=0

2.H2(H)=2 9.5% of H(H), 4% of total, sub=0

2.H4(H)=2 9.5% of H(H), 4% of total, sub=0

1.U(U)=11 16.41%* of total, sub=11

2.U5(U)=6 54.54%* of U(U), 8.9%* of total, sub=6

3.U5b(U)=4 66.7%* of U5(U), 36.36%* of U(U), 6%* of total, sub=0

3.U5a(U)=2 33.3%* of U4(U), 18.2%* of U(U), 3%* of total, sub=0

2.U4(U)=3 27.27%* of U(U), 4.47%* of total, sub=1

3.U4a(U)=1 100% of U4(U), 27.27% of U(U), 4.47% of total, sub=0

2.U2(U)=1 9.1%* of U(U), 1.5%* of total, sub=0

2.U1(U)=1 9.1%* of U(U), 1.5%* of total, sub=0

1.T(T)=10 15%* of total, sub=1

2.T1(T)=1 100% of T(T), 15% of total, sub=0

1.J(J)=8 12%* of total, sub=8

2.J1(J)=6 75%* of J(J), 9%* of total, sub=6

3.J1a(J1)=5 83.3%* of J1(J), 62.5%* of J(J), 7.46%* of total, sub=0

3.J1b1(J)=1 16.7%* of J1(J), 12.5%* of J(J), 1.5%* of total, sub=0

1.W(W)=5 7.4%* of total, sub=0

1.I1(I)=2 3%* of total, sub=0

1.N1b(N)=1 1.5%* of total, sub=0

1.X(X)=1 1.5%* of total, sub=0

1.HV0(HV0)=1 1.5%* of total, sub=0

Slovakia total, mtDNA=200

1.H(H)=94 47%* of total, sub=69(H*=25)

2.H1(H)=33 47.8% of H(H), 22.4% of total, sub=12

3.H1b(H)=7 58.3% of H1(H), 28% of H(H), 13.1% of total, sub=0

3.H1a(H)=5 41.6% of H1(H), 20% of H(H), 9.36% of total, sub=0

2.H5(H)=12 17.4% of H(H), 8% of total, sub=9

3.H5a(H)=9 100% of H5(H), 17.4% of H(H), 8% of total, sub=0

2.H6(H)=8 11.6% of H(H), 5.45% of total, sub=0

2.H2(H)=5 7.24% of H(H), 3.4% of total, sub=1

3.H2a(H)=1 100% of H2(H), 7.24% of H(H), 3.4% of total, sub=0

2.H7(H)=4 5.8% of H(H), 2.7% of total, sub=0

2.H4(H)=4 5.8% of H(H), 2.7% of total, sub=0

2.H11a(H)=3 4.34% of H(H), 2% of total, sub=0

1.U(U)=31 15.5%* of total, sub=31

2.U5(U)=16 51.6%* of U(U), 8%* of total, sub=16

3.U5b(U)=12 75%* of U5(U), 38.7%* of U(U), 6%* of total, sub=0

3.U5a(U)=4 25%* of U5(U), 13%* of U(U), 2%* of total, sub=0

2.U4(U)=11 35.48%* of U(U), 5.5%* of total, sub=6

3.U4a(U)=6 100% of U4(U), 35.48% of U(U), 5.5% of total, sub=0

2.U2(U)=2 6.45%* of U(U), 1%* of total, sub=0

2.U1(U)=1 3.225%* of U(U), 0.5%* of total, sub=0

2.U7(U)=1 3.225%* of U(U), 0.5%* of total, sub=0

1.T(T)=22 11%* of total, sub=4

2.T1(T)=4 100% of T(T), 11% of total, sub=0

1.J(J)=18 9%* of total, sub=18

2.J1(J)=16 89%* of J(J), 8%* of total, sub=16

3.J1c(J)=11 68.75%* of J1(J), 61.1%* of J(J), 5.5%* of total, sub=0

3.J1a(J)=4 255* of J1(J), 22.2%* of J(J), 2%* of total, sub=0

3.J1b1(J)=1 6.25%* of J1(J), 5.5%* of J(J), 0.5%* of total, sub=0

2.J2a(J)=2 11.1%* of J(J), 1%* of total, sub=0

1.I(I)=10 5%* of total, sub=9

2.I1(I)=8 89% of I(I), 4.4% of total, sub=0

2.I3(I)=1 11% of I(I), 0.55% of total, sub=0

1.HV0(HV0)=8 4%* of total, sub=0

1.W(W)=6 3%* of total, sub=0

1.K(K)=3 1.5%* of total, sub=0

1.X(X)=3 1.5%* of total, sub=0

1.L2a(L2)=2 1%* of total, sub=0

1.M(M)=2 1%* of total, sub=2

2.M1b1a(M)=1 50%* of M(M), 0.5%* of total, sub=0

2.M35b(M)=1 50%* of M(M), 0.5%* of total, sub=0

1.N1b(N)=1 0.5%* of total, sub=0

Syria, total mtDNA=234

1.H(H)=57 24.36%* of total, sub=0(H(-)=1)

1.J(J)=27 11.5%* of total, sub=0

1.T(T)=26 11.1%* of total, sub=0

1.U(U)=24 10.2%* of total, sub=0

1.K(K)=24 10.2%* of total, sub=0

1.HV(HV)=18 7.7%* of total, sub=0, HV(-)=1), -(HV)=1

1.L(L)=14 6%* of total, sub=14

2.L2(L2)=8 57%* of L(L), 3.4%* of total, sub=0

2.L3(L3)=6 42.8%* of L(L), 2.56%* of total, sub=0

1.N(N)=11 4.7%* of total, sub=10

2.N1(N)=10 100% of N(N), 4.7% of total, sub=0

1.W(W)=8 3.4%* of total, sub=0

1.R0(R0)=6 2.56%* of total, sub=0

1.R(R)=6 2.56%* of total, sub=0, R(-)=1

1.X(X)=4 1.7%* of total, sub=0

1.V(V)=3 1.28%* of total, sub=0

1.M(M)=2 0.85%* of total, sub=0

1.I(I)=2 0.85%* of total, sub=0

1.A(A)=1 0.425%* of total, sub=0

1.JT(JT)=1 0.425%* of total, sub=0

Tunisia total, mtDNA=160

1.L(L)=56 35%* of total, sub=56

2.L3(L3)=23 41%* of L(L), 14.375%* of total, sub=18(L3*=50)

3.L3e(L3)=6 33.3%* of L3(L3), 13.6%* of L(L), 4.8%* of total, sub=6

4.L3e5(L3)=4 66.7%* of L3e(L3), 22.2% of L3(L3), 9% of L(L), 3.2% of total, sub=0

4.L3e2b(L3)=1 16.7%* of L3e(L3), 5.5% of L3(L3), 2.28% of L(L), 0.8% of total, sub=0

4.L3e1b(L3)=1 16.7%* of L3e(L3), 5.5% of L3(L3), 2.28% of L(L), 0.8% of total, sub=0

3.L3c2(L3)=5 27.8% of L3(L3), 11.4% of L(L), 4% of total, sub=0

3.L3f(L3)=3 16.7% of L3(L3), 6.8% of L(L), 2.4% of total, sub=3

4.L3f1b(L3)=2 66.7%* of L3f(L3), 11.1% of L3(L3), 4.56% of L(L), 1.6% of total, sub=0

4.L3f3(L3)=1 33.3%* of L3f(L3), 5.55% of L3(L3), 2.28% of L(L), 0.8% of total, sub=0

3.L3b2(L3)=2 11.1% of L3(L3), 4.56% of L(L), 1.6% of total, sub=0

3.L3h1b1a(L3)=1 5.55 of L3(L3), 2.28% of L(L), 0.8% of total, sub=0

3.L3d1c(L3)=1 5.55 of L3(L3), 2.28% of L(L), 0.8% of total, sub=0

2.L2(L2)=20 35.7%* of L(L), 12.5%* of total, sub=20

3.L2a(L2)=18 90%* of L2(L2), 32%* of L(L), 11.25%* of total, sub=7

4.L2a1(L2)=7 100% of L2a(L2), 90% of L2(L2), 32% of L(L), 11.25% of total, sub=0

3.L2e(L2)=2 10%* of L2(L2), 3.57%* of L(L), 1.25%* of total, sub=0

2.L1(L2)=12 21.4%* of L(L), 7.5%* of total, sub=12

3.L1b(L1)=9 75%* of L1(L1), 16%* of L(L), 5.625%* of total, sub=0

3.L1c2(L2)=2 16.7%* of L1(L1), 3.57%* of L(L), 1.25%* of total, sub=0

3.L1a(L1)=1 8.35%* of L1(L1), 1.785%* of L(L), 0.625%* of total, sub=0

2.L0a1(L0)=1 1.785* of L(L), 0.625%* of total, sub=0

1.H(H)=50 31.25%* of total, sub=1

2.H6(H)=1 100% of H(H), 31.25% of total, sub=0

1.U(U)=24 15%* of total, sub=24

2.U6(U)=10 41.7%* of U(U), 6.25%* of total, sub=10

3.U6a(U)=9 90%* of U6(U), 37.5%* of U(U), 5.625%* of total, sub=4

4.U6a1(U)=4 100% of U6a(U), 90% of U6(U), 37.25% of U(U), 5.625% of total, sub=0

3.U6c(U)=1 10%* of U6(U), 4.167%* of U(U), 0.625%* of total, sub=0

2.U8b(U)=8 33.3%* of U(U), 5%* of total, sub=0

2.U5(U)=2 8.3%* of U(U), 1.25%* of total, sub=2

3.U5b(U)=1 50%* of U5(U), 4.167%* of U(U), 0.625%* of total, sub=0

3.U5a1(U)=1 50%* of U5(U), 4.167%* of U(U), 0.625%* of total, sub=0

2.U1a(U)=2 8.3%* of U(U), 1.25%* of total, sub=2

2.U3(U)=2 8.3%* of U(U), 1.25%* of total, sub=2

1.T(T)=8 5%* of total, sub=5(T*=3)

2.T1(T)=3 60% of T(T), 3% of total, sub=1

3.T1a(T)=1 100% of T1(T), 60% of T(T), 3% of total, sub=0

2.T2(T)=2 40% of T(T), 2% of total, sub=2

3.T2b(T)=1 50%* of T2(T), 20% of T(T), 1% of total, sub=0

3.T2c(T)=1 50%* of T2(T), 20% of T(T), 1% of total, sub=0

1.HV(HV)=8 5%* of total, sub=0

1.J(J)=4 2.5%* of total, sub=4

2.J2(J)=3 75%* of J(J), 1.875%* of total, sub=0

2.J1b(J)=1 25%* of J(J), 0.625%* of total, sub=0

1.M1(M)=3 1.875%* of total, sub=0

1.V(V)=3 1.875%* of total, sub=0

1.K(K)=2 1.25%* of total, sub=0

1.X(X)=1 0.625%* of total, sub=0

1.HV0(HV0)=1 0.625%* of total, sub=0

Tunisia, region: Coastal hinterland mtDNA=63

1.L(L)=31 49.2%* of total, sub=31

2.L3(L3)=13 42%* of L(L), 20.6%* of total, sub=13

3.L3e(L3)=6 46%* of L3(L3), 19.3%* of L(L), 9.5%* of total, sub=6

4.L3e5(L3)=4 66.7%* of L3e(L3), 30.7%* of L3(L3), 13%* of L(L), 6.35%* of total, sub=0

4.L3e2b(L3)=1 16.75* of L3e(L3), 7.7%* of L3(L3), 3.22%* of L(L), 1.58%* of total, sub=0

4.L3e1b(L3)=1 16.75* of L3e(L3), 7.7%* of L3(L3), 3.22%* of L(L), 1.58%* of total, sub=0

3.L3f(L3)=3 23%* of L3(L3), 9.67%* of L(L), 4.76%* of total, sub=3

4.L3f1b(L3)=2 66.7%* of L3f(L3), 15.38%* of L3(L3), 6.45%* of L(L), 3.17%* of total, sub=0

4.L3f3(L3)=1 33.3%* of L3f(L3), 7.7%* of L3(L3), 3.22%* of L(L), 1.58%* of total, sub=0

3.L3b2(L3)=2 15.4%* of L3(L3), 6.4%* of L(L), 3.17%* of total, sub=0

3.L3d1c(L3)=1 7.7%* of L3(L3), 3.2%* of L(L), 1.585%* of total, sub=0

3.L3h1b1a(L3)=1 7.7%* of L3(L3), 3.2%* of L(L), 1.585%* of total, sub=0

2.L2(L2)=10 32.2%* of L(L), 15.87%* of total, sub=10

3.L2a(L2)=8 80%* of L2(L2), 25.8%* of L(L), 12.7%* of total, sub=7

4.L2a1(L2)=7 100% of L2a(L2), 80% of L2(L2), 25.8% of L(L), 12.7% of total, sub=0

3.L2e(L2)=2 205* of L2(L2), 6.45%* of L(L), 3.17%* of total, sub=0

2.L1(L1)=7 22.58%* of L(L), 11.1%* of total, sub=7

3.L1b(L1)=5 71.4%* of L1(L), 16%* of L(L), 8%* of total, sub=0

3.L1c2(L1)=2 28.57%* of L1(L1), 6.45%8 of L(L), 3.17%* of total, sub=0

2.L0a1(L0)=1 3.22%* of L(L), 1.585* of total, sub=0

1.H(H)=14 22.2%* of total, sub=1

2.H6(H)=1 100% of H(H), 22.2% of total, sub=0

1.U(U)=9 14.28%* of total, sub=9

2.U6=5 55.6%* of U(U), 8%* of total, sub=5

3.U6a(U)=4 80%* of U6(U), 44.4%* of U(U), 6.35%* of total, sub=0

3.U6c(U)=1 20%* of U6(U), 11.1%* of U(U), 1.58%* of total, sub=0

2.U1a(U)=2 22.2%* of U(U), 3.17%* of total, sub=0

2.U3(U)=1 11.1%* of U(U), 1.58%* of total, sub=0

2.U5a1(U)=1 11.1%* of U(U), 1.58%* of total, sub=0

1.T(T)=3 4.76%* of total, sub=3

2.T2(T)=2 66.7%* of T(T), 3.17%* of total, sub=2

3.T2b(T)=1 50%* of T2(T), 33.3%* of T(T), 1.58%* of total, sub=0

3.T2c(T)=1 50%* of T2(T), 33.3%* of T(T), 1.58%* of total, sub=0

2.T1a(T)=1 33.3%* of T(T), 1.585* of total, sub=0

1.J2(J)=3 4.76%* of total, sub=0

1.HV0(HV0)=1 1.587%* of total, sub=0

1.M1(M)=1 1.587%* of total, sub=0

1.K(K)=1 1.587%* of total, sub=0

Tunisia, population: Zriba mtDNA=50

1.H(H)=22 44%* of total, sub=0

1.U(U)=12 24%* of total, sub=12

2.U8b(U)=8 66.7%* of U(U), 16%* of total, sub=0

2.U6a(U)=4 33.3%* of U(U), 8%* of total, sub=3

3.U6a1(U)=3 100% of U6a(U), 33.3% of U(U), 8% of total, sub=0

1.HV(HV)=8 16%* of total, sub=0

1.L(L)=4 8%* of total, sub=4

2.L3*(L3)=2 50%* of L(L), 4%* of total, sub=0

2.L2a(L2)=2 50%* of L(L), 4%* of total, sub=0

1.T*(T)=3 6%* of total, sub=0

1.K(K)=1 2%* of total, sub=0

Tunisia, population: Kesra mtDNA=47

1.L(L)=21 44.68%* of total, sub=21

2.L2a(L2)=8 38.1%* of L(L), 17%* of total, sub=0

2.L3(L3)=8 38.1%* of L(L), 17%* of total, sub=5(L3*=3)

3.L3c2(L3)=5 100% of L3(L3), 38.1% of L(L0, 17% of total, sub=0

2.L1(L1)=5 23.8%* of L(L), 10.6%* of total, sub=5

3.L1b(L1)=4 80%* of L1(L1), 19%* of L(L), 8.5%* of total, sub=0

3.L1a(L1)=1 20%* of L1(L1), 4.75%* of L(L), 2.12%* of total, sub=0

1.H(H)=14 30%* of total, sub=0

1.U(U)=3 6.38%* of total sub=3

2.U5b(U)=1 33.3%* of U(U), 2.12%* of total, sub=0

2.U3(U)=1 33.3%* of U(U), 2.12%* of total, sub=0

2.U6a1(U)=1 33.3%* of U(U), 2.12%* of total, sub=0

1.V(V)=3 6.38%* of total sub=0

1.M1(M)=2 4.25%* of total, sub=0

1.T1(T)=2 4.25%* of total, sub=0

1.X(X)=1 2.2%* of total, sub=0

France mtDNA=871

1.H(H)=395 45.3%* of total, sub=0

1.U(U)=126 14.46%* of total, sub=119

2.U5(U)=68 57.14% of U(U), 8.26% of total, sub=17

3.U5a(U)=13 76.47% of U5(U), 43.7% of U(U), 6.32% of total, sub=7

4.U5a1(U)=7 100% of U5a(U), 76.47% of U5(U), 43.7% of U(U), 6.32% of total, sub=5

5.U5a1a(U)=5 100% of U5a1(U), 100% of U5a(U), 76.47% of U5(U), 43.7% of U(U), 6.32% of total, sub=0(U5a1a#=1)

3.U5b(U)=4 23.5% of U5(U), 13.3% of U(U), 2% of total, sub=0

2.U4(U)=22 18.48% of U(U), 2.67% of total, sub=5

3.U4a(U)=5 100% of U4(U), 18.48% of U(U), 2.67% of total, sub=0

2.U2(U)=12 10% of U(U), 1.46% of total, sub=7

3.U2e(U)=7 100% of U2(U), 10% of U(U), 1.46% of total, sub=0

2.U3(U)=9 7.56% of U(U), 1.1% of total, sub=0

2.U8(U)=5 4.2% of U(U), 0.6% of total, sub=0

2.U6a1(U)=2 1.68% of U(U), 0.2% of total, sub=0

2.U7(U)=1 0.8% of U(U), 0.1% of total, sub=0

1.T(T)=78 9%* of total, sub=30

2.T1(T)=19 63.3% of T(T), 5,67% of total, sub=0

2.T2(T)=10 33.3% of T(T), 3% of total, sub=0

2.T3(T)=1 3.3% of T(T), 0.3% of total, sub=0

1.K(K)=73 8.38%* of total, sub=0

1.J(J)=69 8%* of total, sub=11

2.J1(J)=10 9.1% of J(J), 7.2% of total, sub=3

3.J1a(J)=2 66.7% of J1(J), 60.6% of J(J), 4.8% of total, sub=0

3.J1b(J)=1 33.3% of J1(J), 30.3% of J(J), 2.4% of total, sub=0

2.J2(J)=1 9.1% of J(J), 0.7% of total, sub=0

1.V(V)=26 3%* of total, sub=0

1.HV0(HV0)=17 2%* of total, sub=0

1.HV*(HV)=17 2%* of total, sub=0

1.I(I)=16 1.8%* of total, sub=0

1.N(N)=11 1.26%* of total, sub=6(N*=5)

2.N1b(N)=4 66.7%* of N(N), 0.842% of total, sub=0

2.N1a(N)=2 33% of N(N), 0.42% of total, sub=0

1.X(X)=10 1.1%* of total, sub=0

1.W(W)=10 1.1%* of total, sub=0

1.L(L)=8 1%* of total, sub=8

2.L2a1(L2)=3 37.5%* of L(L), 0.3%* of total, sub=0

2.L3(L3)=3 37.5%* of L(L), 0.3%* of total, sub=2(L3*=1)

3.L3f(L3)=1 50% of L3(L3), 18.75% of L(L), 0.17% of total, sub=0

3.L3e2(L3)=1 50% of L3(L3), 18.75% of L(L), 0.17% of total, sub=0

2.L1b(L1)=2 25%* of L(L), 0.23%* of total, sub=1

3.L1b1(L1)=1 100% of L1b(L1), 25% of L(L), 0.23% of total, sub=0

1.R*(R)=7 0.1%* of total, sub=0

1.R0a(R0a)=4 0.46%* of total, sub=0

1.B4a(B)=2 0.23%* of total, sub=0

1.F1a(F)=1 0.1%* of total, sub=0

1.M*(M)=1 0.1%* of total, sub=0

Marbihan, France mtDNA=42

1.H(H)=16 38.1%* of total, sub=0

1.T(T)=8 19%* of total, sub=6

2.T2(T)=3 50% of T(T), 9.5% of total, sub=0

2.T1(T)=2 33.3% of T(T), 6.3% of total, sub=0

2.T3(T)=1 16.7% of T(T), 3.17% of total, sub=0

1.K(K)=7 16.7%* of total, sub=0

1.U(U)=6 14.28%* of total, sub=4

2.U5(U)=4 100% of U(U), 14.28% of total, sub=3

3.U5a(U)=3 100% of U5(U), 100% of U(U), 14.28% of total, sub=2

4.U5a1(U)=2 100% of U5a(U), 100% of U5(U), 100% of U(U), 14.28% of total, sub=1

5.U5a1a#(U)=1 100% of U5a1(U), 100% of U5a(U), 100% of U5(U), 100% of U(U), 14.28% of total, sub=0

1.J(J)=3 7.14%* of total, sub=2

2.J1a(J)=1 50% of J(J), 3.57% of total, sub=0

2.J2(J)=1 50% of J(J), 3.57% of total, sub=0

1.HV0(HV0)=1 2.38%* of total, sub=0

1.X(X)=1 2.38%* of total, sub=0


Normandy, France mtDNA=39

1.H(H)=19 48.7%* of total, sub=0

1.U(U)=9 23%* of total, sub=9

2.U5(U)=5 55.6%* of U(U), 12.8%* of total, sub=5

3.U5a(U)=4 80%* of U5(U), 44.4%* of U(U), 10.25%* of total, sub=3

4.U5a1a(U)=3 100% of U5a(U), 80% of U5(U), 44.4% of U(U), 10.25% of total, sub=0(U5a1a#=1)

3.U5b(U)=1 20%* of U5(U), 11.1%* of U(U), 2.56%* of total, sub=0

2.U4(U)=2 22.2%* of U(U), 5.12%* of total, sub=0

2.U2(U)=2 22.2%* of U(U), 5.12%* of total, sub=0

1.T(T)=6 15.38%* of total, sub=3

2.T2(T)=2 66.7% of T(T), 10.2% of total, sub=0

2.T1(T)=1 33.3% of T(T), 5.1% of total, sub=0

1.K(K)=3 7.7%* of total, sub=0

1.W(W)=1 2.56%* of total, sub=0

1.X(X)=1 2.56%* of total, sub=0


Poitou-Vienne, France mtDNA=44

1.H(H)=20 45.4%* of total, sub=0

1.U(U)=6 13.6%* of total, sub=5(U*=1)

2.U5(U)=2 40% of U(U), 5.4% of total, sub=0

2.U3(U)=2 40% of U(U), 5.4% of total, sub=0

2.U2e(U)=1 20% of U(U), 2.7% of total, sub=0

1.K(K)=6 13.6%* of total, sub=0

1.J(J)=5 11.36%* of total, sub=0

1.B4a(B)=1 2.27%* of total, sub=0

1.F1a(F)=1 2.27%* of total, sub=0

1.HV0(HV0)=1 2.27%* of total, sub=0

1.N*(N*)=1 2.27%* of total, sub=0

1.R*(R)=1 2.27%* of total, sub=0

1.V(V)=1 2.27%* of total, sub=0

1.W(W)=1 2.27%* of total, sub=0


Lyonnais Rhone, France mtDNA=46

1.H(H)=15 32.6%* of total, sub=0

1.J(J)=6 13%* of total, sub=0

1.K(K)=6 13%* of total, sub=0

1.U(U)=3 6.5%* of total, sub=3

2.U5(U)=2 66.7%* of U(U), 4.34%* of total, sub=0

2.U4(U)=1 33.3%* of U(U), 2.17%* of total, sub=0

1.V(V)=3 6.5%* of total, sub=0

1.L(L)=2 4.34%* of total, sub=2

2.L3e2(L3)=1 50%* of L(L), 2.17%* of total, sub=0

2.L2a1(L2)=1 50%* of L(L), 2.17%* of total, sub=0

1.N1(N)=2 4.34%* of total, sub=2

2.N1a(N)=1 50%* of N1(N), 2.17%* of total, sub=0

2.N1b(N)=1 50%* of N(N), 2.17%* of total, sub=0

1.HV0(HV0)=2 4.34%* of total, sub=0

1.HV*(HV)=2 4.34%* of total, sub=0

1.I(I)=1 2.17%* of total, sub=0

1.B4a(B)=1 2.17%* of total, sub=0

1.M*(M)=1 2.17%* of total, sub=0

1.R*(R)=1 2.17%* of total, sub=0

1.X(X)=1 2.17%* of total, sub=0


Perigord-Limousin mtDNA=72

1.H(H)=30 41.67%* of total, sub=0

1.K(K)=11 15.27%* of total, sub=0

1.T(T)=8 11.1%* of total, sub=7

2.T1(T)=4 57.14% of T(T), 6.3% of total, sub=0

2.T2(T)=3 42.8% of T(T), 4.7% of total, sub=0

1.U(U)=8 11.1%* of total, sub=8

2.U5(U)=4 50%* of U(U), 5.5%* of total, sub=3

2.U5b(U)=2 66.7% of U5(U), 33.3% of U(U), 3.7% of total, sub=0

2.U5a1(U)=1 33.3% of U5(U), 16.65% of U(U), 1.85% of total, sub=0

2.U2(U)=3 37.5%* of U(U), 4.167%* of total, sub=0

2.U6a1(U)=1 12.5%* of U(U), 1.38%* of total, sub=0

1.J(J)=6 8.3%* of total, sub=3

2.J1(J)=3 100% of J(J), 8.3% of total, sub=2

3.J1a(J)=1 50% of J1(J), 50% of J(J), 4.167% of total, sub=0

3.J1b(J)=1 50% of J1(J), 50% of J(J), 4.167% of total, sub=0

1.I(I)=2 2.78%* of total, sub=0

1.W(W)=2 2.78%* of total, sub=0

1.HV0(HV0)=2 2.78%* of total, sub=0

1.N1b(N)=1 1.38%* of total, sub=0

1.R0a(R0a)=1 1.38%* of total, sub=0

1.X(X)=1 1.38%* of total, sub=0


Finistere, France mtDNA=20

1.H(H)=9 45%* of total, sub=0

1.U(U)=4 20%* of total, sub=4

2.U5(U)=3 75%* of U(U), 15%* of total, sub=3

3.U5a(U)=2 66.7%* of U5(U), 50%* of U(U), 10%* of total, sub=0

3.U5b(U)=1 33.3%* of U5(U), 25%* of U(U), 5%* of total, sub=0

2.U6a1(U)=1 25%* of U(U), 5%* of total, sub=0

1.V(V)=2 10%* of total, sub=0

1.I(I)=2 10%* of total, sub=0

1.J(J)=2 10%* of total, sub=0

1.K(K)=1 5%* of total, sub=0


Var, France mtDNA=37

1.H(H)=14 37.8%* of total, sub=0

1.U(U)=10 27%* of total, sub=7

2.U5a1(U)=3 42.8% of U(U), 11.5% of total, sub=1

3.U5a1a(U)=1 100% of U5a1(U), 42.8% of U(U), 11.1% of total, sub=0

2.U8(U)=3 42.8% of U(U), 11.5% of total, sub=0

2.U7(U)=1 14.28% of U(U), 3.8% of total, sub=0

1.HV0(HV0)=3 8.1%* of total, sub=0

1.T(T)=3 8.1%* of total, sub=2

2.T2(T)=2 100% of T(T), 8.1% of total, sub=0

1.V(V)=2 5.4%* of total, sub=0

1.K(K)=2 5.4%* of total, sub=0

1.I(I)=2 5.4%* of total, sub=0

1.R0a(R0a)=1 2.7%* of total, sub=0


Poitou Vendee, France mtDNA=80

1.H(H)=46 57.5%* of total, sub=0

1.U(U)=7 8.75%* of total, sub=7

2.U2e(U)=3 42.8%* of U(U), 3.75%* of total, sub=0

2.U4(U)=2 28.57%* of U(U), 2.5%* of total, sub=0

2.U5(U)=2 28.57%* of U(U), 2.5%* of total, sub=0

1.J(J)=6 7.5%* of total, sub=0

1.K(K)=6 7.5%* of total, sub=0

1.T*(T)=4 5%* of total, sub=0

1.V(V)=3 3.75%* of total, sub=0

1.HV*(V)=3 3.75%* of total, sub=0

1.HV0(HV0)=2 2.5%* of total, sub=0

1.I(I)=2 2.5%* of total, sub=0

Maine-Anjou-Maine-et Loire, France mtDNA=82

1.H(H)=28 34.14%* of total, sub=0

1.T(T)=9 11%* of total, sub=1(T*=8)

2.T1(T)=1 100% of T(T), 11% of total, sub=0

1.U(U)=4 4.8%* of total, sub=4

2.U2e(U)=2 50%* of U(U), 2.4%* of total, sub=0

2.U5(U)=1 25%* of U(U), 1.2%* of total, sub=0

2.U3(U)=1 25%* of U(U), 1.2%* of total, sub=0

1.HV0(HV0)=4 4.8%* of total, sub=0

1.J(J)=3 3.65%* of total, sub=0

1.V(V)=2 2.4%* of total, sub=0

1.I(I)=1 1.2%* of total, sub=0

1.X(X)=1 1.2%* of total, sub=0

1.R*(R)=1 1.2%* of total, sub=0

1.K(K)=1 1.2%* of total, sub=0

1.HV*(HV)=1 1.2%* of total, sub=0


Bearn-Pyrennees-Atlantiques, France mtDNA=81

1.H(H)=47 58%* of total, sub=0

1.J(J)=14 17.28%* of total, sub=0

1.U(U)=7 8.64%* of total, sub=7

2.U4=5 71.45* of U(U), 6.17%* of total, sub=2

3.U4a(U)=2 100% of U4(U), 71.45% of U(U), 6.17% of total, sub=0

2.U5(U)=2 28.57%* of U(U), 2.47%* of total, sub=0

1.V(V)=4 5%* of total, sub=0

1.K(K)=3 3.7%* of total, sub=0

1.T1(T)=3 3.7%* of total, sub=0

1.X(X)=2 2.47%* of total, sub=0

1.R*(R)=1 1.23%* of total, sub=0


Britanny-Loire-Atlantique, France mtDNA=75

1.H(H)=40 53.3%* of total, sub=0

1.U(U)=14 18.7%* of total, sub=14

2.U5(U)=5 35.7%* of U(U), 6.7%* of total, sub=0

2.U4(U)=3 21.4%* of U(U), 4%* of total, sub=2

3.U4a(U)=2 100% of U4(U), 21.4% of U(U), 4% of total, sub=0

2.U3(U)=3 21.4%* of U(U), 4%* of total, sub=0

2.U8(U)=2 14.28%* of U(U), 2.7%* of total, sub=0

2.U2e(U)=1 7.14%* of U(U), 1.33%* of total, sub=0

1.T(T)=5 6.7%* of total, sub=1(T*=4)

2.T1(T)=1 100% of T(T), 6.7% of total, sub=0

1.K(K)=4 5.3%* of total, sub=0

1.I(I)=2 2.7%* of total, sub=0

1.J(J)=2 2.7%* of total, sub=0

1.V(V)=2 2.7%* of total, sub=0

1.W(W)=2 2.7%* of total, sub=0

1.R0a(R0a)=1 1.3%* of total, sub=0

1.X(X)=1 1.3%* of total, sub=0

1.HV*(HV)=1 1.3%* of total, sub=0

1.HV0(HV0)=1 1.3%* of total, sub=0


Langueda, France mtDNA=85

1.H(H)=30 35.3%* of total, sub=0

1.U(U)=16 18.8%* of total, sub=15(U*=1)

2.U5(U)=12 80% of U(U), 15% of total, sub=0

2.U4(U)=2 13.3% of U(U), 2.5% of total, sub=0

2.U3(U)=1 6.65% of U(U), 1.25% of total, sub=0

1.T(T)=13 15.3%* of total, sub=1(T*=12)

2.T1(T)=1 100% of T(T), 15.3% of total, sub=0

1.J(J)=7 8.2%* of total, sub=0

1.K(K)=5 5.88%* of total, sub=0

1.HV*(HV)=4 4.7%* of total, sub=0

1.L(L)=2 2.35%* of total, sub=2

2.L3f(L3)=1 50%* of L(L), 1.17% of total, sub=0

2.L1b1(L3)=1 50%* of L(L), 1.17% of total, sub=0

1.V(V)=2 2.35%* of total, sub=0

1.W(W)=2 2.35%* of total, sub=0

1.R0a(R0a)=1 1.17%8 of total, sub=0

1.N1b(N1)=1 1.17%8 of total, sub=0

1.X(X)=1 1.17%8 of total, sub=0

1.I(I)=1 1.17%8 of total, sub=0

Picardi-Samme, France mtDNA=79

1.H(H)=28 35.4%* of total, sub=0

1.T(T)=10 12.6%* of total, sub=6(T*=4)

2.T1(T)=6 100% of T(T), 12.6% of total, sub=0

1.K(K)=9 11.4%* of total, sub=0

1.U(U)=8 10%* of total, sub=8

2.U5(U)=6 75%* of U(U), 7.6%* of total, sub=0

2.U4(U)=1 12.5%* of U(U), 1.26%* of total, sub=0

2.U3(U)=1 12.5%* of U(U), 1.26%* of total, sub=0

1.J(J)=7 8.86%* of total, sub=0

1.HV*(HV)=5 6.33%* of total, sub=0

1.N(N)=4 5%* of total, sub=1(N*=3)

2.N1b(N)=1 100% of N(N), 5% of total, sub=0

1.V(V)=3 3.8%* of total, sub=0

1.W(W)=1 1.26%* of total, sub=0

1.X(X)=1 1.26%* of total, sub=0

1.R*(R)=1 1.26%* of total, sub=0

1.L2a1(L2)=1 1.26%* of total, sub=0

1.I(I)=1 1.26%* of total, sub=0

Maine Anjou-Sunthe, France mtDNA=36

1.H(H)=17 47.2%* of total, sub=0

1.U(U)=7 18.4%* of total, sub=7

2.U4(U)=4 57.145* of U(U), 11.1%* of total, sub=0

2.U5(U)=2 28.57%* of U(U), 5.5%* of total, sub=0

2.U3(U)=1 14.28%* of U(U), 2.7%* of total, sub=0

1.K(K)=5 13.8%* of total, sub=0

1.T*(T)=3 8.3%* of total, sub=0

1.J(J)=2 5.5%* of total, sub=0

1.N1a(N1)=1 2.7%* of total, sub=0

1.HV*(HV)=1 2.7%* of total, sub=0

Yeman-total, mtDNA=300

1.L(L)=115 38.3%* of total, sub=115

2.L3(L3)=49 42.6%* of L(L), 16.3%* of total, sub=47

3.L3e(L3)=17 36% of L3(L3), 15.4% of L(L), 6% of total, sub=17

4.L3e3(L3)=11 64.7%* of L3e(L3), 23.4% of L3(L), 10% of L(L), 3.8% of total, sub=0

4.L3e1(L3)=4 23.5%* of L3e(L3), 8.5% of L3(L3), 3.6% of L(L), 1.4% of total, sub=3

5.L3e1a(L3)=3 100% of L3e1(L3), 23.5% of L3e(L3), 8.5% of L3(L3), 3.6% of L(L), 1.4% of total, sub=0

4.L3e2b(L3)=2 11.76%* of L3e(L3), 4.25% of L3(L3), 1.8% of L(L), 0.7% of total, sub=0

3.L3f(L3)=8 17% of L3(L3), 7.25% of L(L), 2.78% of total, sub=7(L3f*=1)

4.L3f1(L3)=7 100% of L3f(L3), 17% of L3(L3), 7.25% of L(L), 2.78% of total, sub=0

3.L3d(L3)=11 23.4% of L3(L3), 10% of L(L), 3.8% of total, sub=10

4.L3d1(L3)=9 90% of L3d(L3), 21% of L3(L3), 9% of L(L), 3.4% of total, sub=0

4.L3d2(L3)=1 10% of L3d(L3), 2.3% of L3(L3), 1% of L(L), 0.38% of total, sub=0

3.L3b(L3)=5 10.6% of L3(L3), 4.5% of L(L), 1.7% of total, sub=0

3.L3i(L3)=3 6.38% of L3(L3), 2.72% of L(L), 1% of total, sub=1

4.L3i2 former L3w(L3)=1 100% of L3i(L3), 6.38% of L3(L3), 2.72% of L(L), 1% of total, sub=0

3.L3h(L3)=2 4.25% of L3(L3), 1.8% of L(L), 0.7% of total, sub=0

3.L3h(L3)=2 4.25% of L3(L3), 1.8% of L(L), 0.7% of total, sub=0

3.L3x2(L3)=1 2.1% of L3(L3), 1% of L(L), 0.34% of total, sub=0

2.L0(L0)=26 22.6%* of L(L), 8.67%* of total, sub=26

3.L0a(L0)=24 92.3%* of L0(L0), 20.8%* of L(L), 8%* of total, sub=23

4.L0a2(L0)=15 65.2% of L0a(L0), 60% of L0(L0), 13.6% of L(L), 5.2% of total, sub=0

4.L0a1(L0)=8 34.7% of L0a(L0), 32% of L0(L0), 7.25% of L(L), 2.78% of total, sub=3

5.L0a1a(L0)=3 100% of L0a1(L0), 34.7% of L0a(L0), 32% of L0(L0), 7.25% of L(L), 2.78% of total, sub=0

3.L0k(L0)=2 7.7%* of L0(L0), 1.7%* of L(L), 0.6%* of total, sub=0

2.L2(L2)=18 15.6%* of L(L), 6%* of total, sub=18

3.L2a(L2)=14 77.7%* of L2(L2), 12.17%* of L(L), 4.67%* of total, sub=10

4.L2a1(L2)=10 100% of L2a(L2), 77.7% of L2(L2), 12.17% of L(L), 4.67% of total, sub=7

5.L2a1a(L2)=5 71.14% of L2a1(L2), 71.14% of L2a(L2), 55.5% of L2(L2), 8.7% of L(L), 3.33% of total, sub=0

5.L2a1b(L2)=2 28.57% of L2a1(L2), 28.57% of L2a(L2), 22.2% of L2(L2), 3.47% of L(L), 1.3% of total, sub=0

3.L2b(L2)=2 11.1%* of L2(L2), 1.7%* of L(L), 0.6%* of total, sub=0

3.L2d1(L2)=2 11.1%* of L2(L2), 1.7%* of L(L), 0.6%* of total, sub=0

2.L6(L6)=14 12%* of L(L), 4.67%* of total, sub=0

2.L1(L1)=4 3.47%* of L(L), 1.3%* of total, sub=4

3.L1c(L1)=3 75%* of L1(L1), 2.6%* of L(L), 1%* of total, sub=3

4.L1c1(L1)=2 66.7%* of L1c(L1), 50%* of L1(L1), 1.7%* of L(L), 0.67%* of total, sub=0

4.L1c2(L1)=1 33.3%* of L1c(L1), 25%* of L1(L1), 0.85%* of L(L), 0.335%* of total, sub=0

3.L1b(L1)=1 25%* of L1(L1), 0.8%* of L(L), 0.33%* of total, sub=0

2.L4(L4)=4 3.47%* of L(L), 1.33%* of total, sub=3(L4*=1)

3.L4a*(L4)=2 66.7% of L4(L4), 2.3% of L(L), 0.885 of total, sub=0

2.L4g(L4)=1 33.3% of L4(L4), 1.1% of L(L), 0.44% of total, sub=0

1.J(J)=42 14%* of total, sub=37

2.J1(J)=35 94.6% of J(J), 13.2% of total, sub=24

3.J1c(J)=12 50% of J1(J), 47.3% of J(J), 6.6% of total, sub=0

3.J1a(J)=6 25% of J1(J), 23.65% of J(J), 3.3% of total, sub=0

3.J1b(J)=6 25% of J1(J), 23.65% of J(J), 3.3% of total, sub=0

2.J2(J)=2 5.4% of J(J), 0.7% of total, sub=1

3.J2a(J)=1 100% of J2(J), 5.4% of J(J), 0.7% of total, sub=0

1.R0a(R0a)=28 9.3%* of total, sub=0

1.K(K)=18 6%* of total, sub=0

1.U(U)=17 5.67%* of total, sub=15

2.U1(U)=3 20% of U(U), 1.1% of total, sub=1

3.U1a(U)=1 100% of U(U), 1.1% of total, sub=0

2.U2(U)=3 20% of U(U), 1.1% of total, sub=2

3.U2b(U)=2 100% of U(U), 1.1% of total, sub=0

2.U3(U)=2 13.3% of U(U), 0.75% of total, sub=0

2.U4(U)=2 13.3% of U(U), 0.75% of total, sub=0

2.U7(U)=2 13.3% of U(U), 0.75% of total, sub=0

2.U9(U)=1 6.65% of U(U), 0.375% of total, sub=0

2.U5a1a(U)=1 6.65% of U(U), 0.375% of total, sub=0

2.U8b(U)=1 6.65% of U(U), 0.375% of total, sub=0

1.M(M)=16 5.3%* of total, sub=13(M*=3)

2.M3(M)=6 46% of M(M), 2.46% of total, sub=3(M3*=3)

3.M3a(M)=3 100% of M3(M), 46% of M(M), 2.46% of total, sub=0

2.M1(M)=3 23% of M(M), 1.23% of total, sub=1

3.M1a(M)=1 100% of M1(M), 23% of M(M), 1.23% of total, sub=0

2.M4(M)=1 7.7% of M(M), 0.4% of total, sub=0

2.M2b(M)=1 7.7% of M(M), 0.4% of total, sub=0

2.M40(M)=1 7.7% of M(M), 0.4% of total, sub=0

2.M30(M)=1 7.7% of M(M), 0.4% of total, sub=0

1.T(T)=15 5%* of total, sub=9(T*=6)

2.T1(T)=6 66.7% of T(T), 33.3% of total, sub=0

2.T5(T)=3 33.3% of T(T), 16.65% of total, sub=0

1.N1(N1)=14 4.67%* of total, sub=14

2.N1a(N1=9 64.28%* of N1(N1), 3%* of total, sub=0

2.N1d(N1)=3 21.4%* of N1(N1), 1%* of total, sub=0

2.N1b(N)=1 7.13%* of N1(N1), 0.33%* of total, sub=0

2.N1c(N)=1 7.13%* of N1(N1), 0.33%* of total, sub=0

1.H(H)=14 4.67%* of total, sub=0

1.HV1(HV1)=5 1.67%* of total, sub=0

1.R*(R)=5 1.67%* of total, sub=0

1.X2(X)=4 1.3%* of total, sub=0

1.R2(R)=3 1%* of total, sub=0

1.HV*(HV)=2 0.65%* of total, sub=0

1.W(W)=2 0.65%* of total, sub=0

Yeman-West Coast mtDNA=67

1.J(J)=20 30%* of total, sub=17(J*=3)

2.J1(J)=17 100% of J(J), 30% of total, sub=10

3.J1c(J1)=8 80% of J1(J), 80% of J(J), 23.88% of total, sub=0

3.J1b(J)=2 20% of J1(J), 20% of J(J), 6% of total, sub=0

1.L(L)=18 26.86%* of total, sub=18

2.L3(L)=10 55.5%* of L(L), 15%* of total, sub=8

3.L3f(L)=3 37.5% of L3(L3), 20.8% of L(L), 5.6% of total, sub=2(L3f*=1)

4.L3f1(L3)=2 100% of L3f(L3), 37.5% of L3(L3), 20.8% of L(L), 5.6% of total, sub=0

3.L3b(L)=3 37.5% of L3(L3), 20.8% of L(L), 5.6% of total, sub=0

3.L3e3(L3)=2 25% of L3(L3), 14% of L(L), 3.7% of total, sub=0

2.L0a(L0)=4 22.2%* of L(L), 6%* of total, sub=3(L0a*=1)

3.L0a2(L0)=3 100% of L0a(L0), 22.2% of L(L), 6% of total, sub=0

2.L2a(L2)=3 16.7%* of L(L), 4.47%* of total, sub=2

3.L2a1(L2)=2 100% of L2a(L2), 16.7% of L(L), 4.47% of total, sub=1

4.L2a1b(L2)=1 100% of L2a19L2), 100% of L2a9L2), 16.7% of L(L), 4.47% of total, sub=0

2.L4g(L4)=1 5.5%* of L(L), 1.5%* of total, sub=0

1.H(H)=6 9%* of total, sub=0

1.U(U)=5 7.46%* of total, sub=3(U*=2)

2.U3(U)=1 33.3% of U(U), 2.48% of total, sub=0

2.U7(U)=1 33.3% of U(U), 2.48% of total, sub=0

2.U4(U)=1 33.3% of U(U), 2.48% of total, sub=0

1.R0a(R0a)=4 6%* of total, sub=0

1.K(K)=3 4.47%* of total, sub=0

1.T*(T)=3 4.47%* of total, sub=0

1.N1d(N1)=3 4.47%* of total, sub=0

1.R2(R)=2 3%* of total, sub=0

1.R*(R)=1 1.5%* of total, sub=0

1.W(W)=1 1.5%* of total, sub=0

1.M40(M)=1 1.5%* of total, sub=0

Yeman-East mtDNA=39

1.L(L)=24 61.5%* of total, sub=24

2.L3(L3)=11 45.8%* of L(L), 28.2%* of total, sub=11

3.L3e(L3)=4 36.36%* of L3(L3), 16.7%* of L(L), 10.2%* of total, sub=4

4.L3e1a(L3)=3 75%* of L3e(L3), 27.27%* of L3(L3), 12.5%* of L(L), 7.7%* of total, sub=0

4.L3e2b(L3)=1 25%* of L3e(L3), 9.1%* of L3(L3), 4.16%* of L(L), 2.56%* of total, sub=0

3.L3d1(L3)=3 27.27%* of L3(L3), 12.5%* of L(L), 7.7%* of total, sub=0

3.L3f1(L3)=2 18.185* of L3(L3), 8.3%* of L(L), 5.13%* of total, sub=0

3.L3b(L3)=1 9.1%* of L3(L3), 4.167%* of L(L), 2.56%* of total, sub=0

3.L3w(L3)=1 9.1%* of L3(L3), 4.167%* of L(L), 2.56%* of total, sub=0

2.L0a(L0)=9 37.5%* of L(L), 23%* of total, sub=9

3.L0a2(L0)=7 77.7%* of L0a(L0), 29.16%* of L(L), 18%* of total, sub=0

3.L0a1a(L0)=2 22.2%* of L0a(L0), 8.3%* of L(L), 5.12%* of total, sub=0

2.L2a1(L2)=2 8.3%* of L(L), 5.12%* of total, sub=1

3.L2a1b(L2)=1 100% of L2a1(L2), 8.3% of L(L), 5.12% of total, sub=0

2.L1c1(L1)=2 8.3%* of L(L), 5.12%* of total, sub=0

1.J1(J)=3 7.7%* of total, sub=3

2.J1b(J)=2 66.7%* of J1(J), 5.12%* of total, sub=0

2.J1c()=1 33.3%* of J1(J), 2.56%* of total, sub=0

1.M(M)=3 7.7%* of total, sub=3

2.M2b(M)=1 33.3%* of M(M), 2.56%* of total, sub=0

2.M3(M)=1 33.3%* of M(M), 2.56%* of total, sub=0

2.M30(M)=1 33.3%* of M(M), 2.56%* of total, sub=0

1.H(H)=2 5.1%* of total, sub=0

1.T(T)=2 5.1%* of total, sub=0

1.U(U)=2 5.1%* of total, sub=2

2.U5a1a(U)=1 50%* of U(U), 2.56%* of total, sub=0

2.U1a1(U)=1 50%* of U(U), 2.56%* of total, sub=0

1.R*(R)=1 2.56%* of total, sub=0

1.N1a(N1)=1 2.56%* of total, sub=0

1.HV1(HV1)=1 2.56%* of total, sub=0